tag:blogger.com,1999:blog-85020134522329120142024-03-13T12:26:54.820-07:00MEMS InsiderMEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.comBlogger20125tag:blogger.com,1999:blog-8502013452232912014.post-24753197080152399142013-12-09T07:09:00.000-08:002013-12-09T07:09:40.288-08:00MEMS: An Enabler of the Next Internet Revolution<div class="MsoNormal">
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Micro-electromechanical
systems (MEMS) and sensor fusion will play a critical role in enabling a
more intelligent and intuitive Internet of Things (IoT)—one that will
revolutionize the consumer space forever. The MEMS and sensor technology
is here today and now is the time to harness it for your products and
position yourself for this exciting future. I encourage you to read on
and learn about some great examples of MEMS enabling IoT.<br /><i>-Karen Lightman, Executive Director, MEMS Industry Group</i></div>
<strong><br /><br /> MEMS: An Enabler of the Next Internet Revolution</strong><br /> <i>Written by: Howard Wisniowski, President of HW Marketing Group.</i></div>
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<span style="font-family: inherit;">The next internet revolution is
shaping up and <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=3933">MEMS</a>
is poised to play an important role. Commonly referred to as the <a href="http://en.wikipedia.org/wiki/Internet_of_Things">Internet of Things</a>
(IoT) or <a href="http://en.wikipedia.org/wiki/Machine_to_machine">Machine to
Machine (M2M) communications</a>, this revolution consists primarily of machines
talking to one another, with computer-connected humans observing, analyzing and
acting upon the resulting 'big data' explosion it produces. While the first
internet/web revolution changed the world profoundly, the disruptive nature of MEMS,
M2M and the Internet of Things has the potential to change it even more as the
big data machine will no longer be dependent on human data entry. The internet
traffic will be automatically generated by millions of 'things' from which we can
retool large parts of the world for better efficiency, security and
environmental responsibility.<o:p></o:p></span></div>
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<span style="font-family: inherit;">The enabling qualities of MEMS
sensors quickly come to mind since they are increasingly becoming cheap,
plentiful and can communicate, either directly with the internet or with internet-connected
devices. Almost anything to which you can attach a sensor — a football helmet,
an automobile, a smartphone, a cow in a field, a container on a cargo vessel,
the air-conditioning unit in your office, a lamppost in the street — can become
a node in the Internet of Things. Be it on location, altitude, velocity,
temperature, illumination, motion, power, humidity, blood sugar, air quality,
soil moisture... you name it, MEMS-based sensors will play an important role in
gathering and/or disseminating data from millions of devices. <o:p></o:p></span></div>
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<span style="font-family: inherit;">Deeper into the signal chain,
however, is another class of MEMS devices that is evolving and will have a
profound impact. At the heart of all the “connected” devices will be a
component that provides the timing that enables all communication to occur. <o:p></o:p></span></div>
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<span style="font-family: inherit;">In the past, timing components have
typically been manufactured from quartz crystals, a nearly century-old
technology unsuitable for integration into small, low power connectivity ICs. In
contrast, a new generation of MEMS timing devices are appearing and are offered
by companies such as <a href="http://www.sand9.com/">Sand 9</a>, <a href="http://www.silabs.com/Pages/default.aspx">Silicon Labs</a>,<a href="http://www.idt.com/"> IDT</a>, and <a href="http://www.sitime.com/">SiTime</a>.
Major advantages of MEMS timing devices include vibration immunity, shock
resistance, power supply noise immunity, small package dimensions, and reliable
operation at high sustained temperatures. Additionally, sourcing MEMS timing devices is significantly easier
that quartz. Leadtimes are shorter, the ability to react to sudden upside is
much faster, and the ability to leverage semiconductor batch manufacturing
enables cost benefits as volumes scale.<o:p></o:p></span></div>
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<span style="font-family: inherit;">For the IoT market, small size is a
key factor. New timing devices are now available in ultra-small WLCSPs and can
be co-packaged with Bluetooth Smart ICs. An example of this is <o:p></o:p></span></div>
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<span style="font-family: inherit;">Sand 9’s MEMS resonators. Rugged,
simplified Bluetooth Smart SiPs with the smallest dimensions and lowest power
requirements are one of the factors driving Bluetooth adoption and IoT growth by enabling
applications such as new
industrial designs for wearable devices and tags. With
an ever increasing number of Bluetooth devices able to connect
wirelessly, both the ecosystem and each device in it will increase in value and
usefulness.<o:p></o:p></span></div>
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<span style="font-family: inherit;">Speaking of smaller size, zero operate power, and higher
performance, another MEMS technology is emerging that will also impact product
designs serving the IoT trends. MEMS switches are now being introduced that
require no power to switch while robust enough to handle 300mW of ‘carry power’ performing as a
sensor, high carry current switch or both. Announced earlier this year<a href="http://www.cotorelay.com/">, Coto Technology’s</a> RedRock™ MEMS-based magnetic reed switch is
the latest example and is currently the world's smallest single-pole, single
throw (SPST) switch at only 2-by-1 millimeter (with an even smaller one on the
way). It is activated or closed by a magnetic field of less than 25 milliTeslas
while being highly directional, making it virtually immune to stray magnetic
fields. Applications that benefit include ultra-small hearing aids, implantable
insulin pumps, capsule endoscopes in-a-pill, and even devices that track birds,
land animals and sharks off the coast of Chatham Massachusetts, all products
connected for data logging and programming. <o:p></o:p></span></div>
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<span style="font-family: inherit;">There’s many exciting market possibilities for
MEMS-based products in the emerging world of the Internet of Things as products
become smaller, increase in capability and machine-to-machine communication
grows in importance. I’ve only touched the surface and I’m sure there are many
more examples in this continually evolving landscape as suppliers continue to
roll out products with greater capabilities and enable applications that were
not possible before. Who is next? Share your thoughts.</span>MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-19258179609773638992013-11-27T09:02:00.001-08:002013-11-27T09:02:25.528-08:00Are Hardware Hubs Coming?<em>Submitted by: <strong>Bryon Moyer</strong>, Editor of <a href="http://www.eejournal.com/blog">EE Journal</a></em><br />
<br />
Sensor fusion has been all the rage over the last year. We’ve all watched as numerous companies – both makers of sensors and the “sensor-agnostic” folks – have sported dueling algorithms. Sensor fusion has broadened into “data fusion,” where other non-sensor data like maps can play a part. This drama increasingly unfolds on microcontrollers serving as “sensor hubs.”<br />
<br />
But there’s something new stirring. While everyone has been focusing on the algorithms and which microcontrollers are fastest or consume the lowest power, the suggestion is being put forward that the best way to execute sensor fusion software may not be in software: it may be in hardware.<br />
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Software and hardware couldn’t be more different. Software is highly flexible, runs anywhere (assuming compilers and such), and executes serially. (So far, no one that I’m aware of has proposed going to multicore sensor fusion for better performance.) Hardware is inflexible, may or may not depend on the underlying platform, and can run blazingly fast because of massive inherent parallelism.<br />
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Of course, then there’s the programmable version of hardware, the FPGA. These are traditionally large and power-hungry – not fit for phones. A couple companies – QuickLogic and Lattice – have, however, been targeting phones with small, ultra-low-power devices and now have their eyes on sensor hubs. Lattice markets their solution as a straight-up FPGA; QuickLogic’s device is based on FPGA technology, but they bury that fact so that it looks like a custom part.<br />
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Which solution is best is by no means a simple question. Hardware can provide much lower power – unless sensor hub power is swamped by something else, in which case it theoretically doesn’t matter. (Although I’ve heard few folks utter “power” and “doesn’t matter” in the same breath.) Non-programmable hardware is great for standard things that are well-known; software is good for algorithms in flux. Much of sensor fusion is in flux, although it does involve some elements that are well-understood.<br />
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Which suggests that this might not just be a hardware-vs-software question: perhaps some portions remain in software while others get hardened. But do you end up with too many chips then? A sensor hub is supposed to keep calculations away from the AP. If done as hardware, that hub can be an FPGA (I can’t imagine an all-fixed-hardware hub in this stage of the game); if done in software, the hub can be a microcontroller. But if it’s a little of both hardware and software, do you need both the FPGA and the microcontroller?<br />
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Then there’s the issue of language. High-level algorithms start out abstract and get refined into runnable software in languages like C. Hardware, on the other hand, relies on languages like VHDL and Verilog – very different from software languages. Design methodologies are completely different as well. Converting software to optimal hardware automatically has long been a holy grail and remains out of reach. Making that conversion is easier than it used to be, and tools to help do exist, but it still requires a hardware guy to do the work. The dream of software guys creating hardware remains a dream.<br />
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There’s one even more insidious challenge implicit in this discussion: the fact that hardware and software guys all too often never connect. They live in different silos. They do their work during different portions of the overall system design phase. And hardware is expected to be rock solid; we’re more tolerant (unfortunately) of flaws in our software – simply because they’re “easy” to fix. So last-minute changes in hardware involve far whiter knuckles than do such out-the-door fixes in software.<br />
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This drama is all just starting to play out, and the outcome is far from clear. Will hardware show up and get voted right off the island? Or will it be incorporated into standard implementations? Will it depend on the application or who’s in charge? Who will the winners and losers be?<br />
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Gather the family around and bring some popcorn. I think it’s going to be a show worth watching.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-57729067490680625272013-11-06T07:22:00.001-08:002013-11-15T12:34:44.854-08:00Design Enablement and the Emergence of the Near Platform - Guest Blog by Peter Himes of Silex Microsystems<div class="MsoNormal">
I am pleased to bring you this blog by <b>Silex Microsystem’s
Peter Himes</b>, vice president marketing & strategic alliances. Peter reflects
on MEMS and while other might lament at the conundrum of the uniqueness of all
MEMS process (you can hum it to the tune initially coined by Jean Christophe
Eloy of “one process, one product”) Peter instead sees opportunity. Through
this challenge, Peter sees opportunity for innovation and collaboration. And
what pleases me the most about his musings on MEMS is that the basic thesis
that is my mantra: <span style="mso-spacerun: yes;"> </span>“to succeed in MEMS,
you can’t go at it alone – you must partner.” In this example he describes
Silex’s partnership with A.M. Fitzgerald and Associates and their Rocket MEMS
program. Read on, plug in and share your thoughts on how you’ve creatively
sparked innovation in your own company; especially if you come up with the same
reflection: in MEMS, it takes a village; you can’t go at it alone. </div>
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<span style="font-size: large;"><b>Design Enablement and the Emergence of the Near Platform</b></span></h2>
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What does it mean to enable a MEMS design? Is it enough to
have silicon wafers, a clean room and some tools? What bridges the idea to
product?<br />
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Traditionally it has meant a series of trials based on past
experiences on conceiving of a process flow which results in the final desired
structure. What steps are possible? What materials can be used? How will it
react to the process and how will it perform after all processing is done? All of
these questions need to be understood simultaneously. Being able to do this
consistently over many different projects is how Silex helps the most
innovative MEMS companies get their ideas to high volume manufacturing.</div>
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But in markets where MEMS is becoming mainstream, where
acceptance of MEMS technologies is encouraging traditional and non-traditional
customers alike to consider their own MEMS programs, is this enough to enable
the rapid growth of MEMS going forward? Is every MEMS device trapped in a
paradigm of custom process development and new materials development? Does
everything require MEMS PhD expertise to engineer a perfect solution? In a
market where customers are looking for customized MEMS devices AND rapid time
to market, can they have both?</div>
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The core of MEMS still lies in the custom process
integration and the universe of MEMS devices is still expanding, pushed by the
dark energy of innovation. Our SmartBlock™ approach to process integration is
why we can execute on these challenges in a consistent and high quality way.
But it still takes the time and effort of customized processes to achieve full
production qualification, so we also believe that another model is possible,
and we are beginning to see it emerge.</div>
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Process integration into a foundry environment is something
we also call Design Enablement, because a successful MEMS process enables
designs to be turned into an actual product. But the power of design enablement
is somewhat muted if the echo only rings once. The true power of Design
Enablement is when the process can resonate over many products or many
redesigns of the same product. This would break the “one product, one process”
paradigm and is what we believe is the next phase in the MEMS industry.</div>
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<a href="http://2.bp.blogspot.com/-e1lL0TyW0nI/UnpcFngZWyI/AAAAAAAAADI/OWyt8zfeXH0/s1600/Rocket+MEMS.jpg" imageanchor="1" style="margin-left: 1em; margin-right: 1em;"><img border="0" height="287" src="http://2.bp.blogspot.com/-e1lL0TyW0nI/UnpcFngZWyI/AAAAAAAAADI/OWyt8zfeXH0/s320/Rocket+MEMS.jpg" width="320" /></a></div>
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Alissa Fitzgerald of AMFitzgerald & Associates had a
dilemma and an idea. To her, the normal route for MEMS development was
difficult from the start: begin with an idea and use a university or research lab to get a prototype out. Once it is successful, contact a production MEMS foundry to manufacture it - only to find out there are still months or years of process qualification ahead. What if she could collaborate with a
foundry from the start and define a product design platform <u>and</u> a
process flow simultaneously? Using known process capabilities of an existing
foundry, build and characterize the product to that process, so that both the
processing window <u>and</u> the product spec windows are defined
simultaneously. Then you have a process platform that is solid, “de-risked,”
and ready to take customers to market quickly.</div>
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This is the idea behind the AMFitzgerald RocketMEMS program
and Silex’s support and partnership in the initiative. And it results in
something which is not fully customized for each new product, yet is not
completely and rigidly fixed either. Rather, it is a “Near Product Platform”
made possible by the design enablement of the Silex process integration
approach and AMFitzgerald’s product design framework and methodology. It allows
for product specific variability without breaking the mold out of which the
process was cast.</div>
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And it works.</div>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-38624940487136199572013-05-13T06:04:00.000-07:002013-05-13T08:48:43.544-07:00Who's Driving the MEMS Evolution Revolution Now? (Part 3 of 3)<br />
<h2 class="entry-title">
Who’s Driving the MEMS Evolution Revolution Now? (Part 3 of 3)</h2>
<div class="entry-content">
It is my pleasure to present the conclusion of the guest blog trilogy
on the MEMS Evolution Revolution, written by my colleague, and
long-time MEMS industry insider, Howard Wisniowski. So far in this
series, Howard has taken us with him to "visit" member companies Qualtré
and WiSpry, taught us about bulk acoustic wave (BAW) solid state MEMS
gyroscopes, radio frequency (RF) MEMS, and an innovative application
called "Tunable Antennae." In part three, we will be introduced to one
of the many new MEMS-based technologies coming to the forefront, MEMS
timing devices. We will also take a look at Sand 9, another start up
and MIG member that has developed a truly disruptive timing device.<br />
<br />
I hope you are as excited as I was to read this the final installment
to the series, and I welcome you share your stories of other MEMS start
ups that are breaking out in their own markets. Whether it be in
agriculture or acoustics, healthcare or helicopters, MEMS truly <i>are</i> everywhere and it’s likely the innovative smaller companies who will spread it further, faster and for longer. <b>Viva la Revolution!</b><br />
<br />
<br />
<div align="center" style="text-align: center;">
<b>Who’s Driving the MEMS Evolution Revolution Now?</b></div>
<div style="text-align: center;">
<b>Part 3<br />
Howard Wisniowski, Freelance Editor<br />
</b></div>
<br />
Although MEMS inertial sensors received most of the attention during
the first and second waves of MEMS technology adoption in the 1990s and
2000s, many new MEMS-based technologies are going to be taking center
stage during the current decade. Micro-electromechanical system (MEMS)
timing devices are one good example.<br />
<b><br />MEMS Oscillators<br />
</b><br />
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MEMS-based oscillators are an emerging class of highly miniaturized,
batch manufacturable timing devices that are more rugged, use less power
and are more immune to electromagnetic interference than the
well-established quartz-based oscillators. They also play an important
role by enabling synchronicity and stable operation in complex
electronic devices, from smartphones and tablets to industrial test and
measurement systems and communications infrastructure equipment — for
applications such as ethernet timing, network timing and cellular base
stations. Users not only benefit from better performance in smaller
geometries, these MEMS timing products can be integrated / co-packaged
with standard semiconductor IC’s to enhance performance, simplify end
system design, and optimize board real estate.<br />
<br />
Sand 9 (Cambridge, MA), another startup and MIG member, has developed
a MEMS timing-device platform that is truly disruptive. The company’s
technology is the industry’s first to achieve the stringent phase noise
and short-term stability performance requirements for wireless and wired
applications where mobile devices are susceptible to malfunctions when a
device is dropped and the quartz is dislodged. The spurious-free
resonator design – which can enhance network efficiency due to reduced
packet loss – can also result in fewer dropped calls. Mobile devices
also can easily lose GPS lock and may drop calls due to the limitations
of quartz. Also being addressed are earlier MEMS challenges including
high power consumption, large phase noise, strong jitter, frequency
jumps and strong spurious output. While previous solutions were OK for
low-end timing solutions, they are less acceptable for precision timing
requirements of 3G, 4G or GPS applications. Sand 9’s spurious-free
resonator design can enhance network efficiency due to reduced packet
loss – resulting in fewer dropped calls. Combined with high immunity to
noise, shock and lead-free reflow temperatures, the Sand 9
high-precision platform also addresses temperature compensated crystal
oscillator (TCXO) weaknesses that system designers have been forced to
work around for decades.<br />
<br />
From a process innovation standpoint, Sand 9 is developing
piezoelectric MEMS products which are roughly 100x more efficient at
converting electrical energy to mechanical and back to electrical energy
again than electrostatic. This means better performance in smaller
geometries while improving quality (no moving plates = no stiction).
These developments are aimed at overcoming disadvantages of quartz-based
devices that include manufacturing cost, longer procurement times,
scalability and susceptibility to shock damage.<br />
<br />
Industry watchers and analysts have taken notice. According to <a href="http://cts.businesswire.com/ct/CT?id=smartlink&url=http%3A%2F%2Fwww.semico.com&esheet=50314237&lan=en-US&anchor=Semico+Research&index=4&md5=9fdc4b1af15bb9b9f3803575d0470502" target="_blank">Semico Research</a>,
the MEMS oscillator market is still at a nascent stage, representing
less than one percent of the total timing market of $6.3 billion. By
offering drop-in replacement – and technical benefits over established
silicon quartz crystal timing devices – MEMS companies have already
begun to capture market share from the legacy suppliers: quartz crystal
manufacturers. According to their estimates, the global market for MEMS
oscillators was $21.4 million in 2010 and is expected to reach $312
million by 2014, with consumer products representing nearly half of the
market. With disruptive MEMS technologies like MEMS oscillators getting
traction, the third wave of MEMS adoption is off and running. </div>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-5779452941980608472013-05-06T06:07:00.003-07:002013-05-06T08:53:38.877-07:00Who’s Driving the MEMS Evolution Revolution? (Part 2 of 3)I am pleased to bring you the second part of a three part series on
the MEMS Evolution Revolution, written by my colleague, and long-time
MEMS industry insider, Howard Wisniowski. So far in this series, Howard
has taken us with him to "visit" member company Qualtré, and taught us
about bulk acoustic wave (BAW) solid state MEMS gyroscopes. In part 2,
we will begin to learn about radio frequency (RF) MEMS, an innovative
application called "Tunable Antennae," and a start up who is pioneering
the advances of this new technology.<br />
<br />
I hope you are as excited as I am to read this series, and I welcome
you share your stories of other MEMS startups that are breaking out in
their own markets, whether it be in agriculture or acoustics; healthcare
or helicopters. MEMS truly <i>is</i> everywhere and it’s likely the
innovative smaller companies who will spread it further, faster and for
longer. Viva la Revolution!<br />
<div style="text-align: center;">
<b><br /><br />Who’s Driving the MEMS Evolution Revolution Now?</b></div>
<div style="text-align: center;">
<b>Part 2 of 3</b></div>
<div style="text-align: center;">
<b>Howard Wisniowski, Freelance Editor</b></div>
<div style="text-align: left;">
What’s most exciting about MEMS technology is watching <i>how</i>
it is evolving. As a participant in the MEMS industry for over 15
years, I have witnessed much of the evolution and revolution take place.
In Part 1, I highlighted an innovative and disruptive inertial MEMS
technology referred to as bulk acoustic wave (BAW) technology. This new
class of solid state stationary gyroscopes is opening up many new
application possibilities by being able to meet the performance, size,
cost, and reliability requirements for many emerging MEMS inertial
sensor applications.</div>
Part 2 focuses on radio frequency (RF) MEMS and a very innovative and
disruptive application referred to as tunable antennae. It is hard to
believe that one of the most important parts of a mobile phone is the
antennae, which is very low-tech. With today’s smartphones that
incorporate very sophisticated technology from gazillion-transistor CPUs
controlling everything to state-of-the-art retina display on the front
ends, the antennae for GSM, LTE, WiFi, and Bluetooth, are simply pieces
of metal.<br />
<br />
We all can recall when devout iPhone followers were outraged by the
fact that an Apple device could be defeated when water-filled, fleshy
fingers touched the metal antenna, it attenuated (weakened) the signal
and resulted in dropped calls. The fact of the matter is that every
smartphone has similar issues. Fortunately, for every mobile device
maker, there’s an alternative to normal antennae: RF MEMS.<br />
<br />
RF MEMS, as the name suggests, are semiconductor chips that can alter
their physical (mechanical) state with the application of movable
structures. When applied to an antenna, RF MEMS can be used to make
antennae that automatically tune and re-tune themselves to both incoming
and outgoing signals. For example, if one should put a finger on an RF
MEMS antenna it can automatically re-tune itself so that no calls are
dropped. What’s more, this is an emerging application where IHS iSuppli
has reported that sales of RF MEMS devices are could reach $150 million
by 2015.<br />
<b><br />RF MEMS Antenna Tuners</b><br />
<br />
At WiSpry, a start up in Irvine, CA and another MIG member, they are
pioneering advances in the field of tunable RF technology and addressing
the emerging needs of modern smartphones. Today’s smartphones have a
number of radios to deal with — GSM, 3G, CDMA, W-CDMA, LTE, Bluetooth,
WiFi, and even FM and TV radios in some cases. Each one has its own
silicon circuitry and usually its own antenna too. Additionally, there
are now a burgeoning number of frequency bands needing to be supported
for 4G LTE cellular – ranging today from 700 Mhz to around 3700 Mhz.
What’s more, the 3GPP standards are now allowing more than 43 different
frequencies and there is an emerging demand for "Carrier Aggregation" in
LTE – Advanced, the newest set of standards, which will have
simultaneous "aggregation" of multiple frequencies on a single phone,
allowing huge bandwidth improvements.<br />
<br />
WiSpry’s RF MEMS-based antenna tuner technology will play pivotal
roles in these advancements by potentially enabling devices with just a
single antenna and transceiver. By reducing the number of necessary
components in a handset while allowing the radio front-end to be
programmed to work in any frequency band and with any radio standard
using the same set of hardware, a "World-Phone" architecture is possible
and truly disruptive. Finally, thanks to MEMS, the antennae on mobile
devices will actually function more efficiently as they were initially
intended – to carry and convey data and yes, even your phone calls.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-26298127163468680392013-04-25T11:35:00.004-07:002013-05-06T06:08:16.260-07:00Who's Driving The MEMS Evolution Revolution? Part 1 of 3<!--[if gte mso 9]><xml>
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</xml><![endif]-->I am pleased to bring you part one of a three part series on the MEMS
Evolution Revolution, written by my colleague, and long-time MEMS industry
insider, Howard Wisniowski. Howard takes us with him to "visit" three exciting
MEMS startups that are breaking new ground in the mobile/consumer market. In
part one, we learn about bulk acoustic wave (BAW) solid state MEMS gyroscopes
and meet MIG member company Qualtr<span style="font-size: 10.0pt; line-height: 150%; mso-bidi-font-family: Arial;">é</span>. In parts two and three, we journey to
find out what companies are driving the MEMS evolution revolution with their exciting
nascent disruptive technologies. I hope you are as excited as I am to read this
series and I welcome you share your stories of other MEMS startups that are breaking
out in their own markets, whether it be in agriculture or acoustics; healthcare
or helicopters. MEMS truly <i>is</i> everywhere and it’s likely the innovative
smaller companies who will spread it further, faster and for longer. Viva la
Revolution!<br />
<div align="center" class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in; text-align: center;">
<br /></div>
<div align="center" class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in; text-align: center;">
<b style="mso-bidi-font-weight: normal;"><span style="font-family: "Arial","sans-serif"; font-size: 14.0pt; line-height: 150%;">Who’s
Driving the MEMS Evolution Revolution Now?</span></b></div>
<div align="center" class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in; text-align: center;">
<b style="mso-bidi-font-weight: normal;"><span style="font-family: "Arial","sans-serif"; font-size: 14.0pt; line-height: 150%;">Part
1</span></b></div>
<div align="center" class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in; text-align: center;">
<b style="mso-bidi-font-weight: normal;"><span style="font-family: "Arial","sans-serif"; font-size: 12.0pt; line-height: 150%;">Howard
Wisniowski, Freelance Editor<br /><br /> </span></b></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<span style="color: black; font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">Like the transistor and the microprocessor, MEMS are often
described as a disruptive technology, as in change-the-world,
turn-it-upside-down, rewrite-the-rules-of-the-game. You can forget about this
kind of incremental change, however, fitting easily into corporate business
plans. Few, if any, roadmap processes are available to accommodate new innovative
disruptive technologies that either have the potential to radically change the
way products are currently being produced or are the foundation for products
that might create entirely new industries, nascent disruptive technologies. W</span><span style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">ithin
many established corporate environments, <span style="color: black;">roadmaps all
too often focus on sustaining existing technologies with a mature sales base
and use </span><span style="color: black; mso-themecolor: text1;">variations of tried
and true processes that exist in their fabs. Start-ups don’t have these types
of investments enabling them to build on the shoulders of their predecessors
and develop products that take a fresh look at what benefits product design
engineers are seeking for new and existing end applications.</span></span></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<br /></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<span style="color: black; font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">Today on the "revolution" side, the demand for </span><span style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">MEMS
technology is still booming, thanks to not only to the continued growth of high
volume automotive and consumer applications where MEMS sensors have become
mainstream, but also to the continued development of emerging applications </span><span lang="EN" style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%; mso-ansi-language: EN;">in robotics, energy harvesting, and healthcare. On the "evolution"
side, however, there are even more exciting and disruptive things going on with
MEMS technology that is poised to drive the next wave of MEMS enabled products
and applications. </span><span style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">There are <span style="color: black;">hundreds
of companies, universities, and thousands of researchers around the globe
working on MEMS projects. Many have the underlying technology that is well
beyond the laboratory, ready for deployment, and are now seeking funding. </span></span></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<br /></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<span style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">Highlighting
this very active sector, Yole Development reports on the continuing growth of
emerging MEMS products and applications. Alongside many of the old timers, their
reports cite as many as 50 startups designing emerging MEMS devices that have
the possibility to ramp up to large volumes quickly with growing access to
contract foundries. <span style="mso-spacerun: yes;"> </span></span></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<br /></div>
<div style="line-height: 150%; margin-bottom: .0001pt; margin: 0in;">
<span style="font-family: "Arial","sans-serif"; font-size: 11.0pt; line-height: 150%;">Within
this large field, several new “disruptive” MEMS devices will be highlighted in
this three part series beginning with bulk acoustic wave (BAW) MEMS technology.
This new and disruptive MEMS technology is now being applied to innovative MEMS
gyroscopes.<span style="mso-spacerun: yes;"> </span></span></div>
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<br /></div>
<div class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in;">
<b style="mso-bidi-font-weight: normal;"><span style="font-family: "Arial","sans-serif";">Bulk
acoustic wave (BAW) solid state MEMS gyroscopes</span></b></div>
<div class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in;">
<br />
<span style="color: black; font-family: "Arial","sans-serif";">According to analysts
at IHS iSuppli, the MEMS gyroscope market displaced accelerometers as the
revenue champion in consumer and mobile MEMS applications when revenue grew 66
percent from $394 million in 2010 to $655 million in 2011. While engineers now
design systems that include MEMS gyros as essential components, </span><span style="font-family: "Arial","sans-serif";">particularly designers of mobile
devices, <span style="color: black;">suppliers are scrambling to meet their needs
for </span>low power, small size and low cost.</span></div>
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<br /></div>
<div class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in;">
<span style="font-family: "Arial","sans-serif";">Qualtré, Inc.
(Marlborough, MA) is one MEMS start-up and MIG member that is addressing these
issues with an innovative MEMS technology referred to as bulk acoustic wave
(BAW) technology. BAW technology is now being used to pioneer a new class of
solid state stationary gyroscopes that not only meet power, size and cost
requirements, but also add high performance to the mix. Unlike older MEMS gyro
technologies that use moving masses vibrating at low frequency range of 5 to 50
kHz (I don’t want to get too technical here), BAW MEMS gyros operate in the
megahertz frequency range (1</span><span style="font-family: "Cambria Math","serif"; mso-bidi-font-family: "Cambria Math";">‐</span><span style="font-family: "Arial","sans-serif";">10MHz),
several orders of magnitude higher. This is enabled by </span><span style="color: black; font-family: "Arial","sans-serif"; mso-fareast-font-family: "Times New Roman"; mso-themecolor: text1;">the very stiff nature of the BAW technology.</span><span style="color: black; font-family: "Arial","sans-serif"; mso-themecolor: text1;"> </span><span style="font-family: "Arial","sans-serif";">This stiffness not only results in
MEMS gyros that are insensitive to vibration in the environment but also p</span><span style="color: black; font-family: "Arial","sans-serif"; mso-fareast-font-family: "Times New Roman"; mso-themecolor: text1;">revents stiction both in manufacturing and
during operation in the field, thus</span><span style="font-family: "Arial","sans-serif";">
</span><span style="color: black; font-family: "Arial","sans-serif"; mso-fareast-font-family: "Times New Roman"; mso-themecolor: text1;">removing a major yield and
reliability problem found with the vast majority of other MEMS devices.</span><span style="font-family: "Arial","sans-serif";"> These features results in improved performance
in real world applications where vibrations are present and degrade the operation
of current gyros.</span></div>
<div class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in;">
<br /></div>
<div class="MsoNormal" style="line-height: 150%; margin-bottom: .0001pt; margin-bottom: 0in;">
<span style="font-family: "Arial","sans-serif";">By combining these
performance advantages of the BAW sensor design and the scalability of Qualtré’s
proprietary HARPSS process (High Aspect-Ratio Combined Poly and Single-Crystal
Silicon), BAW MEMS gyros have also demonstrated very stable signals (aka low
drift) which is important for pedestrian navigation, improved noise density for
better resolution and more accurate measurements, and a wider dynamic range
that expands detectable signals. This kind of innovation is what will drive the
next wave of end-product product designs for new and existing applications.</span></div>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-22077294429634852672013-03-27T13:27:00.000-07:002013-03-27T14:20:04.309-07:00Karen’s blog from MEMS Executive Congress: Part 2<div style="-webkit-text-size-adjust: auto; -webkit-text-stroke-width: 0px; background-color: white; color: #474957; font-family: Helvetica, Arial, sans-serif; font-size: 12px; font-style: normal; font-variant: normal; font-weight: normal; letter-spacing: normal; line-height: 16px; margin: 0px; orphans: auto; padding: 0px 0px 10px; text-align: left; text-indent: 0px; text-transform: none; white-space: normal; widows: auto; word-spacing: 0px;">
I last left you hanging, waiting to hear more about the heated conversations between the panelists and the audience – and I have to tell you, it really started heating up in the audience during the energy panel. Oooh baby, it was jumping.<br />
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<a href="http://www.flickr.com/photos/50603106@N08/8554986214/" style="color: #537899;" target="_blank" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignright" height="143" src="http://farm9.staticflickr.com/8093/8554986214_8fdbbe76d1_n.jpg" style="border-width: 0px; display: block; float: right; margin: 5px; padding: 0px;" width="200" /></a><a href="https://www.eiseverywhere.com/ehome/46261/78658/#energy" style="color: #537899;" target="_blank">MEMS in energy</a><span class="Apple-converted-space"> </span>can mean a lot of things – and our panelists diverse perspectives discussed a great deal, but the majority of the audience wanted to focus on the topic of MEMS in energy harvesting. Though not necessarily experts in this field, thankfully our panelists were up to the challenge. Our moderator was Bert Gyselinckx, General Manager, Holst Centre, imec; Wim C. Sinke, Program Development Manager, Solar Energy, Energy Research Centre of the Netherlands; Eric Yeatman, Professor of Microengineering, Deputy Head of Department, Imperial College London; and Harry Zervos, Senior Technology Analyst, IDTechEx. I actually should probably add Rob Andosca of MicroGen Systems as a fifth panelist as he was eager to ask and answer any question from the audience with his<span class="Apple-converted-space"> </span><a href="http://www.microgensystems.co/products.asp" style="color: #537899;">BOLT energy harvester</a><span class="Apple-converted-space"> </span>in hand.<br />
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I loved the diversity of perspective on this panel –Wim for example does not have an entirely MEMS-centric background. His expertise is in solar and photovoltaic energy and he spoke of how multiple technologies will work together to make reliable and sustainable energy system, as well as the importance of portfolio management – combining different energies in an active way to make it work. We in MEMS could learn a lot from guys like Wim (I hope everyone picked up his business card; I know I did).<br />
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The panel also spoke about wireless sensor networks and Harry gave a great overview of the three technologies that are converging: 1. Microgenerators and energy storage (vibration, solar, heat, tree resin, etc.); 2. Ultra low-power electronics (currently being developed) – helping power sensors; and 3. Transmission protocols that don’t need a lot of power to send data. Eric followed up with the poignant view that until things become truly wireless, you can’t really have wireless sensor networks. And once they are wireless how will they be powered – by energy harvesting or battery? This opened the floodgates and I, with microphone in hand had to jog all over the audience to capture the comments and follow-up questions from the audience.<br />
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Let me be diplomatic and say that there is no clear consensus out there on MEMS energy harvesting. And out came the very clever quotes including some of my favorites including this one from Wim: "Don’t look at MEMS as the energy harvesters, MEMS are the enablers to help realize energy savings." And this one from someone (maybe you’ll remember and leave a comment here): "I’m happy to hear everyone in MEMS talking about energy, but I can assure you that not everyone in energy is talking about MEMS...yet." And Bert’s: "MEMS will probably not be main source of energy replacing nuclear power plants soon; but MEMS will enable increased intelligence in energy applications." As great as these sound bytes were, the show stealer came when Rob Andosca stood up and talked about how cows are being used for energy harvesting and gave us the best quote: "You power the Moo-mometer with MEMS because cows get dirty." Tech-Eye reporter Tamlin Magee loved that one, too, and plans to write a story on – perhaps cow-power is the next big thing!<br />
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<a href="http://www.flickr.com/photos/50603106@N08/8554981478/" style="color: #537899;" target="_blank" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignleft" height="143" src="http://farm9.staticflickr.com/8365/8554981478_df5c73bf1f_n.jpg" style="border-width: 0px; display: block; float: left; margin: 5px; padding: 0px;" width="200" /></a>The last panel of the day before the closing keynote was<span class="Apple-converted-space"> </span><a href="https://www.eiseverywhere.com/ehome/46261/78658/#medical" style="color: #537899;" target="_blank">MEMS in medical</a><span class="Apple-converted-space"> </span>with a focus on aging moderated by Frank Bartels, Founder (Bartels Mikrotechnik), President (IVAM). Panelists were: Heribert Baldus, Principal Scientist – Personal Health Solutions, Philips Research; Jérémie Bouchaud, Senior Principal Analyst, MEMS and Sensors, IHS iSuppli; Kimmo Saarela, CEO, TreLab Oy; and Axel Sigmund, National Contact Point MTI/DW and Ambient Assisted Living Joint Programme, VDI/VDE Innovation + Technik GmbH. This was another diverse panel with varying views on how to address the medical and healthcare issues of the world’s aging population.<br />
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<b> </b>When asked how MEMS is enabling a better quality of life with regard to prevention, monitoring, management, replacement and rehab I think Kimmo summed it up best when he said that with MEMS we can put so many things into a small form factor, which entices people to use our products. MEMS sensors allow us to collect raw data from so many sources. Data analysis is the key benefit and is their "value add" to the customer. But the key thing here is that power consumption and size really matter. Heribert added that MEMS is enabling an aging population to detect issues in their daily lives and manage their lives. I like to say it gives them their dignity back – and that is no trivial thing.<br />
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Jérémie spoke of some of the mass markets already present for MEMS in aging including sleep apnea disorders and oxygen therapy. There are also mass markets for MEMS medical applications that are in the hospital (not yet in the home) including disposable blood pressure monitors as well as dialysis and drug infusion applications. This kicked off a discussion about an aging population living at home which is becoming more of a critical issue in Europe, and a main focus of what Axel is addressing at VDI/VDE Innovation + Technik.<br />
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At the close, the panelists were asked what they saw as the future of medical – Heribert said he’d like to see more sensor integration, more intelligence and far less power. Jérémie said he sees a future for gas sensors analyzing the breath (and will not require FDA approval). Axel sees non-invasive diabetes monitoring as having the biggest impact; while Kimmo echoed Heribert and sees a future of more integrated solutions where biometric sensors will give more data and aid early detection and intervention. Frank agreed with Jérémie that gas sensors will be next once the pump issue is solved and that the time for microfluidics is near.<br />
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This final panel set things up perfectly for our closing keynote,<span class="Apple-converted-space"> </span><a href="https://www.eiseverywhere.com/ehome/46261/78657/" style="color: #537899;" target="_blank">Renzo dal Molin</a>, Advanced Research Director, Cardiac Rhythm Management business unit, SORIN GROUP. Renzo gave the presentation "Vision for Implanted Medical Devices Healthcare Solutions and Technical Challenges," which outlined the opportunity for implantable medical devices. He described in detail how</div>
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the next generation of medical devices will come from miniaturization of devices, reduction of power consumption, and wireless capability and yes, even spoke of energy harvesting (you can guess whose ears perked at that statement). Renzo then highlighted how the BioMEMS market is expected to grow from $1.9 B in 2012 to $6.6 B in 2018 thanks to the inclusion of accelerometers in pacemakers and homecare monitors; MEMS sensors for glucose meter connected to smartphones; MEMS microphones for hearing aids as well as MEMS insulin pumps.<br />
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The audience was excited to discuss where Renzo saw the future of BioMEMS going, and where he felt the industry should focus moving forward. Renzo agreed that in the near future (once regulatory hurdles were overcome) patients will be able to monitor their implantable devices on their mobile devices. And he felt the next big thing will be biomarkers, as well as MEMS-enabled devices that could give an ECG will be revolutionary to the medical field.<br />
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<a href="http://www.flickr.com/photos/50603106@N08/8553866337/" style="color: #537899;" target="_blank" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignleft" height="133" src="http://farm9.staticflickr.com/8377/8553866337_5ab7ec6136_n.jpg" style="border-width: 0px; display: block; float: left; margin: 5px; padding: 0px;" width="200" /></a>And with that it was time to break and enjoy a fantastic evening at the Heineken Experience. We took some photographs throughout the day but by far my favorites are the ones we took at the brewery – you should definitely<span class="Apple-converted-space"> </span><a href="http://www.flickr.com/photos/50603106@N08/sets/72157632971615589/" style="color: #537899;" target="_blank">check them out</a>. I would like to close this mega-long blog by thanking everyone who made this second-year<span class="Apple-converted-space"> </span><a href="http://www.memscongress.com/europe" style="color: #537899;" target="_blank">MEMS Executive Congress Europe</a><span class="Apple-converted-space"> </span>a great success from my fabulous MIG Team, to the<span class="Apple-converted-space"> </span><a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=3609" style="color: #537899;" target="_blank">MIG Governing Council</a>, to the<span class="Apple-converted-space"> </span><a href="https://www.eiseverywhere.com/ehome/46261/94251/" style="color: #537899;" target="_blank">Congress EU Steering Committee</a>, to the AMAZING<span class="Apple-converted-space"> </span><a href="https://www.eiseverywhere.com/ehome/46261/78644/" style="color: #537899;" target="_blank">sponsors<span class="Apple-converted-space"> </span></a>(especially those top tier ones who are sponsoring all year long – we love you), the keynotes, the speakers, the attendees (especially the press who attended and those who have posted great stories – hooray!), our fantastic conference organizers at PMMI, and our sister conference folks at Smart Systems Integration. THANK YOU ALL.</div>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-9532086649527483032013-03-25T12:28:00.001-07:002013-03-25T13:10:00.222-07:00Karen’s blog from MEMS Executive Congress: Part 1There were many things that impressed me from hosting the second <a href="https://www.eiseverywhere.com/ehome/46261" target="_blank">MEMS Executive Congress Europe</a>
– and it wasn’t the cold and snow (though it was chilly!). What struck
me the most was how lively, engaged and intelligent the conversations
were, not amongst the panelists but between the audience and the
panelists. Often, Europeans can be conservative and reserved in
conferences, but not this year In fact my favorite quote from one of the
panelists was: "when I agreed to this join this panel I didn’t know I
would be joining a religious war."<br />
<br />
<a href="http://www.flickr.com/photos/50603106@N08/8553889471/" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignleft" height="288" src="http://farm9.staticflickr.com/8105/8553889471_054c3dd9ee_n.jpg" style="margin: 10px;" width="193" /></a>The morning definitely didn’t start off with an aggressive tone as the elegant <a href="https://www.eiseverywhere.com/ehome/46261/78657/" target="_blank">Ralf Schnupp</a>,
Vice President Segment Occupant Safety & Inertial Sensors,
Continental served as our keynote. He focused his discussion on future
trends in automotive with an overview of the megatrends affecting: safe
mobility, clean power, intelligent driving, global mobility and most
importantly, safety, with a goal of zero fatalities and accidents (WOW).
He spoke of the challenges of complex sensor systems as well as the
requirements of such systems. What stuck with me was his statement that "we don’t need more sensors, we need more robust, secure and safe
MEMS/sensors." For sensors I think he’s onto something (because it’s
about the smart sensor integration and the software); although when I
tried out that theory later that week at our sister-conference, Smart
Systems Integration, I was completely shot down (ha!).<br />
<br />
<a href="http://www.flickr.com/photos/50603106@N08/8553886351/" style="clear: right; float: right; margin-bottom: 1em; margin-left: 1em;" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignright" height="171" src="http://farm9.staticflickr.com/8237/8553886351_e43c325cd4_m.jpg" style="margin: 10px;" width="240" /></a>After Schnupp’s keynote came the <a href="https://www.eiseverywhere.com/ehome/46261/78658/#consumer" target="_blank">consumer panel </a>moderated
very capably by Dave Thomas, Marketing Director, Etch Products, SPTS
Technologies. Panelists included: Paul Buijs, General Manager, Bruco
Integrated Circuits bv; Robin Heydon, Global Standards – Research and
Innovation Group, CSR; and Joel Huloux, Director – Standardization and
Industry Alliances, STMicroelectronics. You can probably tell from two
of the four titles that the panel talked A LOT about standardization.
And, yes, that was by design, as it’s an important topic that the MEMS
industry has been working on and partnering with groups like MIPI
Alliance (which Joel chairs).<br />
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<br />
Joel brought a good perspective to the panel because he’s not a MEMS
guy; he’s really an OEM/end-user that having spent over a decade with
handset company Erikson (I want to say 20 years but don’t quote me) and
is now with ST, because of the ST/Erickson joint venture. He said that
MIPI aims to create specifications for mobile interfaces and recently
became interested in MEMS (and joined an important partnership with MEMS
Industry Group) because mobile devices add at least two new MEMS each
year. True, but the question remains, what are you going to standardize?
And with that question, thus opened a little bit of the holy war
amongst the panel and the audience. Clearly it’s an important hot button
issue.<br />
<br />
When asked about the future of consumer electronics, the panelists
all felt that its market strength would continue. Robin felt the most
important impact on the world would be the Internet of things as well
antenna switching (he does work for CSR after all). He also felt that
the next move would be towards peripherals such as the smart watch –
while Paul envisioned a future where we’d all have a “doctor in a watch”
as the next killer app, enabled by MEMS.<br />
<br />
<a href="http://www.flickr.com/photos/50603106@N08/8553884037/" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;" title="MEMS Executive Congress Europe 2013 by MEMSIndustryGroup, on Flickr"><img alt="MEMS Executive Congress Europe 2013" class="alignleft" height="171" src="http://farm9.staticflickr.com/8097/8553884037_34f440f2da_m.jpg" style="margin: 10px;" width="240" /></a>Next up was the <a href="https://www.eiseverywhere.com/ehome/46261/78658/#automotive" target="_blank">automotive panel</a>
moderated ably by Marc Osajda, Director, Pressure Sensor Business Unit,
Freescale Semiconductor – Germany. With panelists: Frédéric Breussin,
Business Unit Manager, MEMS & Sensors, Yole Développement; Pietro
Perlo, Vice President Torino E-District, Interactive Fully Electrical
Vehicles; and Jan Peter Stadler, Senior Vice President of Engineering
Sensors, Automotive Electronics Division, Robert Bosch GmbH. What
surprised me about this panel is how quickly the panelists started
talking about electric bicycles (e-bikes). I actually had to check with
Ralph Schnupp, who was sitting next to me, to confirm that was indeed
what Pietro had started the panelists discussing.<br />
<br />
Marc quickly moved them back to automotive and it was actually quite
comical to watch – Pietro and Jan Peter were sort of like the odd couple
– both representing opposite sides of the spectrum of automotive. While
Pietro focused on totally electric vehicles (including bikes!), Jan
Peter averred that the automobile would evolve, but even by 2020 the
majority of cars will still be run by combustible engines. Frédéric was
well placed as a market analyst to give perspective on current uses of
MEMS and sensors in applications such as night vision, heads up displays
as well as efforts to reduce emissions, increase comfort and increase
safety. What was also clear from all the panelists was that the consumer
world is driving more and more of the automotive world; which is good
for technology, but bad for pricing.<br />
<br />
The best part of the panel was when Marc asked each panelist to
describe what his car would look like in 2025. Frédéric said he’d
finally give in and buy a hybrid, Jan-Peter said he wasn’t sure what
kind of engine but he’d definitely want a car big enough to hold the
wine he’d drive back from Romania and carry his e-bike to all the places
he likes to use them (in the mountains). Lastly, Pietro stole the show
when he said he’d be using a flying an electro-mobility flying car: this is a possibility because we are MEMS!"<br />
<br />
I’ll leave you hanging there, wanting to hear more of the excitement
and challenging conversations at MEMS Executive Congress Europe 2013. A
teaser: The next panel was MEMS in Energy, which discussed energy
harvesting MEMS in depth, and as you can imagine, the opinions varied
widely, to put it mildly. Soon, I’ll also describe to you the MEMS in
Medical, focused on Aging panel which challenged us all to think more
about quality of life issues and what more we can do with MEMS to enable
a better world. So stay tuned, I’ll post my next blog soon.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-26322417865174660662013-02-20T10:34:00.000-08:002013-02-20T11:19:08.220-08:00MEMS Executive Congress Europe 2013 - Amsterdam is THE place to be for the MEMS industry on 12 March!<i><b>By Karen Lightman, Managing Director, MEMS Industry Group</b></i>
<br />
The keynote address at last year’s MEMS Executive Congress Europe stated: "MEMS is only limited by the imagination." MEMS Industry Group (MIG) took that sentiment to heart, and organized a 2013 EU Congress chock full of interesting keynotes, panels, dialogue, and camaraderie. We invited some of the top European companies using and commercializing MEMS to share their insight and imagination on the future of MEMS applications in consumer products, automotive, medical, and energy. If you haven’t already, I strongly encourage you to <a href="https://www.eiseverywhere.com/ehome/46261/78652/" target="_blank">register now</a>.<br />
<br />
On the morning of March 12, our keynote speaker, Ralf Schnupp, VP Segment Occupant Safety & Inertial Sensors of Continental Automotive GmbH, will present <i>Future Trends in Automotive — Smart Systems and Sensors</i>. I am extremely honored to have Dr. Schnupp as our keynote; he is extremely well respected in the industry and I know that he will open the Congress in a big and impressive way. In his keynote, he plans to present a vision of the future of automotive that is very macro/global in its perspective with a balance of "enhanced safety, environmental protection, increased connectivity, and affordable vehicles."<br />
<br />
After Dr. Schnupp’s keynote, we will have a series of panels focused on MEMS in Consumer, Energy, Automotive and Medical. I could write an entire blog just on the panels but I’d rather not – as I’m focusing mainly on the keynotes today...but let’s just say that if you’ve ever been to a Congress before, you know we have a "recipe" for success. This year is no different. We have put together a healthy mix of moderators and panelists sprinkled with a little bit of controversy to make things interesting. Each panelist will bring his own unique perspective on the critical issues affecting the business of MEMS. <br />
<br />
It’s been said that Europe provides a better environment for spawning MEMS innovation. So, I look forward to hearing from our panelists who are a great mix of end-users, academics, analysts and industry leaders who will share their visions on the success and remaining challenges to MEMS commercialization success. Some of the inventive topics our panels and keynotes will address are:<br />
<br />
<ul>
<li><i>Standardization has played an important role in propelling growth in the consumer electronics industry – but what about MEMS? What progress has been made and what challenges remain? </i></li>
</ul>
<ul>
<li><i>What role will MEMS play in the car of the future and how might sensor fusion drive new applications? </i></li>
</ul>
<ul>
<li><i>How do MEMS advance quality of life now and in the future, from chronic disease management to sports rehab?</i></li>
</ul>
<ul>
<li><i>How are MEMS helping alternative energy adoption in Europe and when will MEMS be commercialized in energy harvesting for smaller consumer applications?</i></li>
</ul>
<br />
<ul>
</ul>
Our afternoon keynote will be Renzo Dal Molin, Advanced Research Director SORIN CRM within Cardiac Rhythm Management business unit, SORIN Group. Dr. Dal Molin is again an extremely well-known and respected leader in the field of cardiac medical research and technology. Dr. Dal Molin’s keynote is entitled <i>Vision for Implanted Medical Devices Healthcare Solutions and Technical Challenges</i> and will review how the market for microelectronic implants is growing phenomenally. He will share his vision for this industry and the main drivers of growth, as well as the challenges that lay ahead. I am sure our heads will be buzzing after his keynote and the conversation will take us all the way to our dinner at a place that I’ve always wanted to visit: the Heineken Brewery. Oh yes, we are having a strolling dinner at the world-famous <a href="https://www.eiseverywhere.com/ehome/46261/78661/" target="_blank">Heineken Experience</a>, where, as I have found myself saying "they serve food to accompany the beer." We will have fun. That is for sure. <br />
<br />
I am obviously giving you just a sneak peak – so for complete details, you need to check out our<a href="https://www.eiseverywhere.com/ehome/46261" target="_blank"> full agenda</a> that begins on March 11 with a dessert reception. Yes, it might have been the MIG staff’s idea to have plenty of desserts on hand (perhaps you’ve heard we like chocolate?); but we realized after last year’s inaugural EU Congress that most of our attendees were hanging out in the conference hotel bar anyhow, so we might as well make it an official party. <br />
<br />
But back to what makes the Congress so unique – and why we’ve successfully held the US version for so many years (it will be nine years, this <a href="https://www.eiseverywhere.com/ehome/46261/103333/" target="_blank">November 7-8 in Napa</a>!) and why we are returning to Europe for a second year. MEMS Executive Congress by definition is not a technical conference. It is not a tradeshow. This is a business-based, senior-level, executive conference where commercialization, revenue, and success stories dominate the discussion. As Rich Duncome of HP stated a few years back after delivering his keynote, the Congress is like "networking on steroids." <br />
<br />
In my very humble (and oh so slightly biased) opinion, there is only one place in Europe where global industry luminaries will be talking about where MEMS technology is growing, based on real experiences and real time data. And there is only one place where you can meet them. This compelling one-day event is a MUST for entire the MEMS supply-chain. And oh, have you <a href="http://www.memscongress.com/" target="_blank">registered</a> yet for The MEMS Executive Congress Europe? You don’t want to miss it.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-24884232454648658792012-12-17T13:56:00.000-08:002012-12-18T06:36:11.627-08:00MEMS is happening in Vegas baby, and it’s coming home with you, too<b>By Karen Lightman, managing director, MEMS Industry Group</b><br />
<br />
Everyone knows the famous refrain, "What happens in Vegas, stays in Vegas." But for MEMS, you'll want what happens in Vegas to come home with you. Why? Because MEMS at CES has gone waaaaay beyond sensing your touch and letting you play Angry Birds.<br />
<br />
MEMS Industry Group (MIG) is going back for a second year to International CES -- because MEMS is happening in Vegas. And baby, it's so cool and innovative and its applications are so new and exciting that it's coming home with you, too. At 2013 International CES MEMS will be ever-present; and MIG is helping it stand out even more this year with our half-day <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=4159#conference" target="_blank">MEMS conference track</a> on January 8.<br />
<br />
We will kick off our conference track with a very special keynote from Mr. Klaus Meder, president of Bosch Automotive Electronics, entitled "<a href="http://ces13.mapyourshow.com/5_0/sessions/sessiondetails.cfm?ScheduledSessionID=1DA0CE" target="_blank">The MEMS Generation: Why Miniature 'Machines' are changing the User Experience with Everything."</a> Mr. Meder will discuss the connectivity of the automobile with the consumer, all enabled by the power of MEMS. I spoke with Mr. Meder earlier this fall regarding this keynote and was thrilled to hear his passion for MEMS and the role he sees it playing in what he calls this "interconnected lifestyle." In Meder's keynote, I expect that he will be taking the theory of the Internet of things one step further by demonstrating how a combination of MEMS and sensors are enabling our lives to be untethered by wires or roads. I was given a sneak peek of his presentation and got goose bumps when I saw the car of the future -- and I think you will, too.<br />
<br />
Even though I expect our mouths will be agape after Mr. Meder finishes his keynote, we'll have to compose ourselves and move on with the show. Next up will be our panel "<a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4164#panel1" target="_blank">How to Never Get Lost in a Mall or a Museum: Indoor Navigation and the Smartphone</a>." I am thrilled to see that this technology will soon be available in my smartphone with the aid of a combo of MEMS accelerometers, gyros, magnetometers and pressure sensors, creating a super-intelligent 10-axis mobile device. I am notorious for getting lost inside office buildings and any place where you can't see direct sunlight. I know my children (especially) are looking forward to the day when I have such a smart phone that will allow us to get step-by-step directions of how to find the Abercrombie & Fitch in a shopping mall -- with an ability to see what level it is on. I am going to have fun moderating these panelists and promise not to go <i>too</i> hard on them by asking them when I can pre-order my phone:<br />
<ul>
<li>Dan Brown, CEO, Sensor Platforms</li>
<br />
<li>Seyed Paransun, vice president and general manager, Sensor and Actuator Solutions Division, Freescale Semiconductor</li>
<br />
<li>Benedetto Vigna, corporate vice president and general manager, Analog, MEMS and Sensors Group, Industrial and Multisegment Sector, STMicroelectronics</li>
</ul>
<br />
Next I'll moderate the panel <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4164#panel2" target="_blank">A Whole New Look for Digital Displays</a>. Right now, MEMS-based technologies are the 'secret ingredient' in natural-looking color displays for impressive electronic applications such as the Kindle Fire. Based on the technology such as TI's DLP, developed for rear-projection televisions and home theater systems, MEMS is now leading a renaissance in projection systems through the smallest projector imaginable: the pico projector. I expect that soon we'll have high quality pico projectors in our mobile devices and MEMS-enabled Heads Up Displays assisting with navigation in our automobiles (it's already in use in Japan). This panel will cover the full range of what's hot in MEMS digital displays and you won't want to miss it. Panelists include:<br />
<ul>
<li>Evgeni Gousev, Senior Director of Engineering, Qualcomm Research</li>
<br />
<li>Elan Roth, marketing and business development director, Analog MEMS and Sensors Group mobile projection business, STMicroelectronics</li>
<br />
<li>Dale Zimmerman, vice president of R&D, MicroVision</li>
</ul>
<br />
I expect our last panel <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4164#panel3">MEMS, Signal Quality, Smart Sound and the Mobile Handset</a> is going to possibly be most inspiring of the three panels (feel free to prove me wrong). That's because we're talking about an issue that many of us hold so dear: the quality of our calls on our mobile handsets. Think about it, how many times a day do you drop a call or you can't hear the person on the other end? Isn't that annoying/frustrating? MEMS TO THE RESCUE! It's like the blog I recently wrote for EETimes, "<a href="http://www.eetimes.com/electronics-blogs/other/4402057/A-day-without-MEMS" target="_blank">A day without MEMS</a>" -- well in a way, we are living it, because most of us don't yet have MEMS RF switches or MEMS microphones in our smartphones. C'mon mobile handset manufacturers, get with the program and get us our MEMS! New RF MEMS "tunable antennas," MEMS oscillators and microphones are helping manufacturers to create more physically robust phones while boosting signal integrity and sound quality. I am really looking forward to this discussion because I think they will mainly all agree with each other on how MEMS should be pervasive in every single mobile handset to cure all dropped calls and end all poor quality calls:<br />
<ul>
<li>Kieran Harney, product line director, Analog Devices</li>
<br />
<li>Jeff Hilbert, president and founder, WiSpry</li>
<br />
<li>Davin Yuknis, vice president of sales and marketing, Akustica</li>
</ul>
<br />
So mark your calendars and buy your conference passes now! The MEMS conference session takes place January 8, 2013, 9:00 a.m.-12:00 p.m., in the Las Vegas Convention Center (LVCC) North Hall, Room N264. If you are a MIG member, you automatically get a discount on your conference pass.<br />
<br />
Don't forget that MIG is also hosting the MEMS TechZone, featuring members and partners with live demos of MEMS in consumer applications. The MEMS TechZone is located at the LVCC South Hall 2, Booth 25321. And remember, this time you'll want to take what happens in Vegas home <i>with</i> you.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-22248771773033331972012-10-30T10:02:00.001-07:002012-11-01T14:12:11.921-07:00Preview of the MEMS Technology Showcase at MEMS Executive Congress US 2012If I must tell the truth, the genesis of MEMS Technology Showcase began (as many great ideas do) at a bar over beers, the closing night of MEMS Executive Congress 2010. I was talking with Bryan Hoadley of Movea, who had just spoken on the MEMS in Consumer panel. He and I talked about what the MEMS industry needs -- a way to show how cool the MEMS inside is -- to showcase the "MEMS in the machine" (a marketing theme that we at MEMS Industry Group had just launched earlier that year). And viola! The concept for MEMS Technology Showcase was born.<br />
<br />
My vision was to create a carnival-type atmosphere where OEM/end-user companies would compete to come up on stage while the moderator would be the ringmaster, virtual whip in hand, taming the masses who want a glimpse at the wonder of those magnificent MEMS-enabled products. My ultimate goal was to have companies not wait to release their products at CES in January, but instead, at MEMS Technology Showcase in November. I fantasized that someday even Apple would want to release their latest iPhone at the Congress! -- (Well you must admit there are <i>a lot</i> of MEMS in there!)<br />
<br />
Last year the MEMS Technology Showcase was a huge success -- so big that others even tried to replicate it at their events (I guess it's that expression: "imitation is the best form of flattery," right?) We crowned <a href="http://www.reconinstruments.com/" target="_blank">Recon Instruments</a>' MOD-Live heads-up display for goggles as our winner, and they've gone on to great commercial success and recognition.<br />
<br />
This year we have six finalists, and I am confident that our winner will receive accolades and customer orders galore, and it'll be due in part to those fabulous little MEMS chips inside, enabling all that functionality in a smaller, faster and lower-power form factor with heaps of intelligence to boot.<br />
<br />
I am equally confident in this year's moderator, <a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=51860" target="_new">Shawn G. DuBravac</a>, chief economist and senior director of research, Consumer Electronics Association. <i>(BTW nothing will come close to CES, I was just kidding, Shawn. No hard feelings, right?)</i> Shawn has mastered similar types of competitions for CEA and has already shared his advice on how to mange the "flow" of the competition/panel; his biggest suggestion was to get a HUGE DIGITAL CLOCK like the ones they have at finish lines for marathons. I thought we'd get the whip from my original ringmaster idea...<br />
<br />
Here's a peek at who will be competing in our second annual MEMS Technology Showcase:<br />
<br />
<b>VUE Patch</b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/12-0914a_bm_revisedpatchrendering_frontview_crop.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft" height="128" src="http://memsblog.files.wordpress.com/2012/10/12-0914a_bm_revisedpatchrendering_frontview_crop.jpg?w=229&h=128" title="12-0914a_BM_RevisedPatchRendering_FrontView_crop" width="229" /></a><br />
<br />
<b>BodyMedia</b>'s VUE Patch -- is a seven-day, disposable body-monitoring patch that measures calorie burn, activity levels and sleep patterns, creating a snapshot of lifestyle habits to guide recommendations for weight loss, diabetes management, sports/fitness, corporate wellness, and more.<br />
<br />
<br />
<br />
<b>12-axis Xtrinsic Sensor Platform for Windows 8</b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/freescale-windows-8-certification_crop1.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft size-full wp-image-2392" height="175" src="http://memsblog.files.wordpress.com/2012/10/freescale-windows-8-certification_crop1.jpg?w=225&h=175" title="Freescale Windows 8 Certification_crop" width="225" /></a><br />
<br />
<a href="http://www.freescale.com/" target="_blank"><b>Freescale Semiconductor</b></a>'s <a href="http://www.freescale.com/webapp/sps/site/prod_summary.jsp?code=RDWIN8SNSPLTM" target="_new">12-axis Xtrinsic sensor platform for Windows 8</a> extends sensor fusion in tablets, slates, laptops and other portable devices. This complete hardware and software reference platform fuses accelerometer, magnetometer and gyroscope data using a Freescale ColdFire+ MCU. It also features a 'smart' pressure sensor that provides pressure and altitude data. Certified for <a href="https://sysdev.microsoft.com/en-US/Hardware/lpl" target="_new">Windows 8</a>.<br />
<br />
<br />
<br />
<b>Intel Atom Z2760 for Windows 8 tablets and convertibles<br /></b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/clover-trail-and-tablet_crop.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft wp-image-2388" height="101" src="http://memsblog.files.wordpress.com/2012/10/clover-trail-and-tablet_crop.jpg?w=204&h=101" title="clover-trail-and-tablet_crop" width="204" /></a><br />
<br />
The <b>Intel</b> Atom processor Z2760 ("Clover Trail") was architected specifically for Windows 8. It is based on Intel's 32nm process technology, powers lightweight tablets and convertibles that meet the demands of consumers and business users, and includes outstanding battery life, always-on technology, connected standby and the sleekest designs available. This touch-enabled tablet features a sensor hub microcontroller with an array of physical and logical motion sensors (including accelerometer, magnetometer, gyroscope, fusion sensors (compass, device orientation, and inclinometer), proximity, additional location systems (ALS) and GPS. Certified for <a href="https://sysdev.microsoft.com/en-US/Hardware/lpl" target="_new">Windows 8</a>.<br />
<br />
<br />
<br />
<b>Light Bohrd<br /></b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/lightbohrdproduct_crop.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft wp-image-2391" height="144" src="http://memsblog.files.wordpress.com/2012/10/lightbohrdproduct_crop.jpg?w=187&h=144" style="margin-left: 4px; margin-right: 4px;" title="lightbohrdproduct_crop" width="187" /></a><br />
<br />
<b>Light Bohrd</b>, LLC, is looking to make revolutionary contributions in skateboarding and snowboarding style and safety by adding the world's first motion-activated LED lights to each sport's respective boards. The Light Bohrd LED design uses patent-pending technology to store energy and activate LED lights to illuminate the board's graphics. With technology completely embedded, Light Bohrd's boards are charged wirelessly through magnetic induction and are brought to life by the wave of a magnet. The lights are then activated with motion. A fully charged Light Bohrd will stay lit for up to six hours.<br />
<br />
<br />
<br />
<b>LUMOback</b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/meet_lumo_4_crop.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft wp-image-2387" height="103" src="http://memsblog.files.wordpress.com/2012/10/meet_lumo_4_crop.jpg?w=192&h=103" title="Meet_LUMO_4_crop" width="192" /></a><br />
<br />
<b>LUMOback</b> is a wearable sensor and smartphone app that provides feedback on posture and movement. The sensor band is worn around the waist and gently vibrates when the wearer slouches to remind him/her to sit or stand up straight. The smartphone app displays an avatar that mimics the wearer's movements and posture in real time, capturing that information when he/she sits, stands, walks, runs and sleeps. It is compatible with the iPhone 5, 4S, new iPod touch (5th gen) or new iPad (3rd gen).<br />
<br />
<br />
<br />
<b>Sphero<br /></b><br />
<a href="http://memsblog.files.wordpress.com/2012/10/glossysphero-copy_crop.jpg" style="clear: left; float: left; margin-bottom: 1em; margin-right: 1em;"><img alt="" class="alignleft wp-image-2386" height="143" src="http://memsblog.files.wordpress.com/2012/10/glossysphero-copy_crop.jpg?w=169&h=143" title="GlossySphero copy_crop" width="169" /></a><br />
<br />
<b>Orbotix</b>'s Sphero is the first robotic-ball gaming device controlled with a tilt, touch or swing from a smartphone or tablet. It immerses users in a new type of gameplay called "mixed-reality," in which real and virtual elements are seamlessly merged. Sphero interacts with mobile apps, giving people new ways to test their skills, play games with friends, and more. Users can even employ Sphero as a controller for on-screen gameplay. With free apps being developed continuously, including a mixed-reality version of golf, Sphero provides plenty of gaming thrills.<br />
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<b>Please join us Thursday, November 8, 2012, 11:15 a.m.-12:15 p.m. for the MEMS Technology Showcase at the MEMS Executive Congress. This panel is sponsored by Movea.</b>MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-56941226561515252402012-10-24T08:12:00.000-07:002012-10-26T07:16:52.386-07:00Preview of our fabulous keynotes at MEMS Executive Congress US 2012<i>by Karen Lightman, managing director, MEMS Industry Group</i><br />
<br />
Recently I was talking with a MIG member about what was unique about this year's Congress. I actually surprised myself when I instantly blurted out, "the keynotes!" Normally, I would talk about how cool the MEMS Technology Showcase is (and it is -- really, it is!) And you'll soon hear about it in an upcoming story/blog). But honestly, when I answer from my gut, I gotta go with my initial answer: this year's fabulous keynotes.<br />
<br />
Our opening keynote speaker is <a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=51836" target="_blank">Ajith Amerasekera</a>, TI Fellow, IEEE Fellow, Kilby Labs, Texas Instruments. Ajith was the director of Kilby Labs at TI, which he has described as a "do tank" rather than a "think tank." I am grateful for the time that Ajith has taken from his super-busy schedule solving important challenges at TI to answer a few questions for me, give us a peek inside his brain and preview what he'll be discussing in his keynote, "Ultra Low-Power Electronics in the Next Decade," on the morning of November 8.<br />
<br />
<b>Ajith, with your vast experience at TI in the VLSI Design Labs, director of ASIC Technology Strategy, as well as the director of Kilby Labs, you've gained a great perspective of high tech and how it's evolved since the 1980's. So given your experience, how do you define the shift in electronic technology from centralized and high-touch to ubiquitous and low-touch, and what are the driving forces?</b><br />
<br />
A. The shift is defined by a need for more localized intelligent electronic devices to control and manage our environment -- from home automation to the smart grid. Electronics are enabling us to be more efficient and productive. The ability to build more powerful devices at very low power and cost levels enables us to distribute and embed intelligence widely. TI is a major player in ultra-low power, high-performance, analog chips and embedded processors that are the heart of these new systems.<br />
<br />
<b>Thank you, Ajith. Can you expand on why low-power electronic devices are so important to distributing intelligence across applications in our personal lives, health, transportation, and safety and security?</b><br />
<br />
A. Power is critical to the operation of electronic devices. The more devices used, the more power we need, and the more we need them to be power-efficient. There are also other factors in play such as power distribution and availability, battery management, etc.<br />
<br />
<b>Can you give me some examples, or are we primarily talking about evolutionary advancements in smartphones and tablets?</b><br />
<br />
A. We are talking about advancements in everything. One example is in the infotainment system of an automobile, where the center auto console is controlled by gesture-sensing that can tell if the person interacting is the driver or passenger, thereby limiting distracting behavior (like checking Facebook) for the driver, but allowing it for the passenger. Another example is a project on which we are actively working: the realization of smart buildings, smart cities and smart transportation. These projects require us to sense the environment and then optimize usage against resource availability. Interactive sensing is also useful in wellness management, health management, fitness and sports. Smartphones and tablets are just the tip of the iceberg, in terms of low-power applications that are changing our relationship with electronic devices.<br />
<br />
<b>That is fascinating and I can't wait to hear more in your keynote, because I totally agree with you. But now I've gotta ask more about my favorite acronym, MEMS. What are your thoughts on how MEMS technology enables digital environments that adapt to and anticipate our needs? And where are the biggest potential impacts (positive and negative)?</b><br />
<br />
A. We need to be able to sense our environment. And the key technology that helps us to do that is MEMS. MEMS technology will enable us to recreate the five senses -- touch, smell, hearing, sight, taste -- and will give us the capability to anticipate and adapt our needs. As for impacts, the positive impacts are already visible in the way we interact with our phones and tablets, how our homes manage power usage -- kitchen appliances for baking potatoes to energy efficient dishwashers, for example. Negative impacts include security and safety, which arise when we rely so heavily on electronic technology. However, I am confident that these challenges will be solved.<br />
<br />
<hr />
<br />
And then to top it off, we have an equally amazing keynote in the afternoon. As our closing keynote, I have invited <a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=41963" target="_blank">Robert Brunner</a> who is the founder, creative director and partner of Ammunition, where he communicates strategic innovation through product design, brand and surrounding experience.<br />
<br />
What most impresses me about Robert is that when he's working with the likes of Dr. Dre on his Beats' brand of high-performance headphones and loudspeakers and the Barnes & Noble folks on their Nook, he is always thinking of the human hands that are going to use the end product. He truly understands that it's not the gee-whiz of a technology that will determine the success of a product, but it's the design and how it fits and works with the human -- and the human hands that will make or break the next killer app.<br />
<br />
I am equally grateful to Robert for sharing his brilliance with me and answering a few questions to preview his upcoming keynote. I asked him to tailor his keynote to my MEMS supply chain audience and push them to really think about where their products are ending up: in human hands.<br />
<br />
<b>Robert, what if we in the MEMS industry "build it and no one comes?" In other words, why is the user experience more important than component technology in creating the amazing product breakthroughs that change our world? What are a few examples?</b><br />
<br />
A. While underlying technology is essential to providing a capability to the user, what people really care about is what it does, how it does it, how it feels and how it fits their lives. So it might be a great breakthrough, but if it is not designed for the user in a way that is compelling and desirable, they won't care and it will fail. The iPhone is a perfect example of this. There is tremendous development and technology behind what makes it function the way it does, but what people care about is how it delivers that total user experience. It is why it's such a successful a product.<br />
<br />
<b>Thank you, Robert. Following on that same line of thinking, how can technologists understand and value the user experience as much as they do the underlying technology within? Based on your experience working at Apple, what is the best piece of advice that you can impart to technologists working to create a breakthrough product that will be loved by the masses for its industrial design?</b><br />
<br />
A. First of all, everybody is a designer. That is, anywhere you are on the chain in delivering something into a user's hands, you have a role in enabling an experience and should embrace this responsibility. It is always important to work back from the ideal experience into the device, not the other way around. If you let the technology drive the experience per se, you may end up with something that works, but is difficult, and does not connect with people. As the product is being developed, work with user-experience (UE) or design teams early to define and understand the ideal user scenario, then activate that as a tool to shape the functionality and capabilities of the technology and device. It is truly about an insurance policy for success.<br />
<br />
<b>Again -- fantastic and practical all at the same time. So how can I take this "to the street" as it were? How can MEMS device manufacturers increase the perceived value of their products to customers? How about to end-users? (Will there ever be a campaign for the 'gyro inside,' for example?)</b><br />
<br />
A. Well, this is tricky, as it has to be real. You cannot simply brand something around an ideal unless you have the technology and capability to support it. "Intel Inside" was quite successful as they managed to communicate it as a sort of quality ideal (and forced manufacturers to put the tag on their products!) But today, I think people are suspicious of this unless it goes with an actual capability that is valuable to them. If you successfully embody a user-centric approach to realizing a capability and can define its value to people, then finding a way to succinctly and emotionally communicate this to people can be huge!<br />
<br />
We put this into practice with Beats Audio. We built a brand around an emotional connection to music with our Beats' products, then licensed the underlying algorithm and DSP to other companies, and allowed them to carry the Beats Audio brand on their products. The Beats' symbol carries an emotional meaning with regard to reproducing modern music, so it has value for people that they are willing to buy. If we had not created that value in how people connect to the products' functionality, it would be meaningless.<br />
<br />
Well I hope you are as enthralled with these two guys as I am and will join me for our eighth annual <a href="http://memsindustrygroup.createsend1.com/t/y-l-jthlhky-l-m/" target="_new">MEMS Executive Congress</a> keynotes:<br />
<ul>
<li>Thursday, November 8, 2012, 8:45-9:30 a.m. for "<a href="http://memsindustrygroup.createsend1.com/t/y-l-jthlhky-l-c/" target="_new">Ultra Low-Power Electronics in the Next Decade</a>," with an introduction by Dave Kirsch, vice president and general manager, North America, EV Group.</li>
</ul>
<ul>
<li>Thursday, November 8, 2012, 4:15-5:00 p.m. for "<a href="http://memsindustrygroup.createsend1.com/t/y-l-jthlhky-l-q/" target="_new">Ideas, Not Objects</a>," with an introduction by Mike Rosa, MEMS global product manager, Applied Materials.</li>
</ul>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-47970903820868167842012-10-08T10:22:00.001-07:002012-10-12T06:27:21.764-07:00Preview of MEMS in consumer products panel at MEMS Executive Congress US 2012<b>By Karen Lightman, managing director, MEMS Industry Group</b><br />
<br />
I remember the first time we had a panel on consumer MEMS products at the <a href="http://www.memscongress.com/" target="_blank">MEMS Executive Congress</a>. It was November 2006: Marlene Bourne was our moderator and our panelists were: Frank Melzer (CEO of the newly formed Bosch Sensortec); Benedetto Vigna (back then his title was MEMS business unit director, STMicroelectronics); Mark Martin's predecessor, Bill Giudice, vice president and general manager<i>, </i>Micromachined Products Division, Analog Devices; and Rick Thompson, manager, Advanced RF Technologies, BAE SYSTEMS.<br />
<br />
Well, things sure have changed since then, haven't they? In those days, we were all abuzz about the imminent release of the Nintendo Wii and the amazing impact of the Apple iPod. (The iPhone wouldn't be announced for another two months.) Makes me smile when I think back at how simple and innocent the times were back then...<br />
We've learned a lot over the past six years. While most of the companies from the 2006 consumer panel are still active in MEMS (but only two of the panelists!), the Congress is now focused on hearing from end-users who are driving the market for MEMS. I am honored and truly delighted to have as this year's moderator for "<a href="http://www.eiseverywhere.com/ereg/popups/sessiondetails.php?eventid=35310&sessionid=1994977&sessionchoice=1&" target="_blank">MEMS in Consumer Products</a>," my colleague <a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=53330&%27,%27Evgeni%20Gousev%20%28Moderator%29%27,%27400%27,%27400%27%29;" target="_blank">Evgeni Gousev</a>, senior director, Technology Development, Qualcomm MEMS Technologies, Inc.<br />
<br />
I had the rare delight of discussing the panel topic over dinner with Evgeni when I was in the Bay Area a few weeks ago (for the <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=4150" target="_blank">MEMS workshop MIG did with BSAC</a>). I scribbled my notes in between bites of a delicious, fresh California green salad to get a glimpse of what Evgeni will be discussing with panelists on the topic of MEMS in consumer products.<br />
<br />
<b>Q: Evgeni, I am impressed by the combined breadth of experience of your panelists. Can you give me a little background?</b><br />
<br />
<b>A:</b><a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=56707" target="_blank"> Sanjay Gupta</a> recently left Motorola Mobility where he was vice president of product development. Sanjay has a successful track record of conceptualization, development, and commercialization of complex software and consumer electronics products; was a founding Board member of the Open Mobile Alliance (OMA) and served on the Java Community Process (JCP), ME Executive Committee (EC); and led the standardization of GSM, GPRS and UMTS standards.<br />
<br />
<a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=54976" target="_blank">Dragan Mladenovic</a> is director of business management for Maxim Integrated's Sensor Division. Dragan has an extensive background in the semiconductor industry and has worked on the following projects: automotive airbag satellite sensors; automotive 77GHz radar (based on the SiGe technology); and eCompass (based on the TMR technology). Most recently Dragan has been involved in the 4 degrees of freedom (DoF) MEMS products for automotive safety applications (rollover, dynamic stability control) and 3DoF of 6DoF MEMS products for smartphones, tablets and wearable devices.<br />
<br />
<a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=55403" target="_blank">Will Turnage</a> is vice president of technology and invention at the advertising agency, R/GA. Will is accountable for global technical product innovation and digital experimentation at R/GA; recent projects include Nike+ FuelBand. With a well-earned reputation as an industry thought leader, he has presented his unique perspective at events like SXSW, the Behance Network's 99% Conference, and JSConf.<br />
<br />
<b>Q: Fantastic lineup of panelists who will give us very diverse perspectives on future markets for MEMS in consumer products! Now let's talk about potential questions you'd like to ask these guys. For instance, what drives innovative applications, software and hardware in MEMS? How can companies add value to the MEMS supply chain?</b><br />
<br />
<b>A.</b> Historically it's always been the MEMS technology itself (the "tech push") that has driven the innovation. But this has changed as the demand for consumer products has grown, and cost pressures have risen. Now we are seeing more "market pull", or consumer demand for features enabled by MEMS, with increased opportunities for software integrators and designers to utilize MEMS as an enabling technology.<br />
<br />
Because the consumer products' market is mostly customer-driven, MEMS suppliers are typically delivering technology that is just "good enough." But customers are demanding more, and OEMs are forced to respond in kind. MEMS suppliers are stepping up with sensor-fusion software that supports the MEMS within, to make it easier for OEMs to get what they want, and the application development community also has a role to play. The most successful companies have mobilized and connected to the user community to help develop some of the most creative and practical uses of their products. Their approach proves that you must have all the pieces together -- cooperation between technology and the application folks from the very beginning.<br />
<br />
For mobile devices, the main requirements are "good-enough technology" but also low cost and low power consumption. The industry is doing pretty well on two of the three, but one could argue that there still is room for improvement in other areas in the consumer products market -- especially with respect to power consumption. There are still many untapped opportunities and markets for solutions like energy harvesting and other lower-power options for consumer products. MEMS can and will play a key role here.<br />
<br />
<b>Q. What are the macro societal trends that will drive demand for more consumer products with MEMS inside? What are the challenges?</b><br />
<br />
<b>A.</b> Consumers are expecting -- really -- <i>demanding</i> MEMS-based solutions in their consumer products. That raises the bar even higher -- to the degree that MEMS is expected in every next-generation consumer product. We need to think about what's next and big and really revolutionary in the use and application of MEMS.<br />
<br />
In the mobile space content that is context and location relevant due to advanced sensors are rich MEMS-based opportunities. Monetization of digital content is only in its very formative stages and will grow exponentially when the content is more relevant to the time, environment and context to the content consumer.<br />
<br />
It's also a generational thing. Younger generations use and communicate via consumer products differently. This has and will continue to raise the expectations for MEMS in consumer products. For example, augmented reality (AR) gets a lot of attention. Today we see AR applications gaming, media/advertising, and education. Futurists predict we will likely see AR in visual speech, navigation and discovery, and social networking. With MEMS sensor data, adding connectivity and the cloud, the MEMS infrastructure is strong and will only grow as these macroeconomic trends evolve.<br />
<br />
Thank you, Evgeni. I am really looking forward to hearing more about MEMS in Consumer Products at MEMS Executive Congress US 2012 in Scottsdale, AZ in November!MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-76237961972515543982012-09-26T08:01:00.000-07:002012-09-27T08:04:08.154-07:00MEMS in medical, quality-of-life panel at MEMS Executive Congress US 2012For those of you who have heard me talk about MEMS and medical/quality-of-life (QoL) applications -- I don’t shy away from
calling it “God’s work.” I still get misty-eyed when I think about my
friend’s 10-year-old daughter, Anna, who has Type 1 Diabetes. Last year
I told Anna about technology from <a href="http://www.mchips.com/">MicroCHIPS</a> that (thanks to the wonders of <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=3926">MEMS</a>)
will someday enable her to seamlessly and automatically monitor and
dose her insulin without having to prick her finger and then calculate
and administer a dose before every meal or snack. She’ll get her dignity
back and she’ll improve her quality of life.<br />
<br />
The Holy Grail in medicine is not diagnosing Diabetes, Alzheimer’s, or
even obesity -- it’s figuring out what’s next and how to deal with it.
MEMS technology can and will help to navigate that path.<br />
With MEMS technology fundamental to new medical/QoL devices and
applications, understanding opportunities in this rapid-growth market is
more important than ever. At the <a href="http://www.memscongress.com/us">MEMS Executive Congress US 2012</a>,
we’ve lined up a panel of industry experts to discuss how MEMS
continues to play a critical role in the development of new technologies
that assist with patient monitoring, diagnostics, therapy and portable
health care.<br />
<br />
To preview our panel, I’ve invited my moderator, <a href="http://www.eiseverywhere.com/ereg/popups/speakerdetails.php?eventid=35310&speakerid=50488&language=eng&back=1">Jeannette F. Wilson</a>, product line manager, sensor and actuator solution division (SASD) / AISG, <a href="http://www.freescale.com/">Freescale Semiconductor</a>, to introduce our panelists and share her thoughts on what they will discuss.<br />
<br />
<b>Q: Jeannette – who is on this fabulous MEMS in Medical/QoL panel?</b><br />
<br />
<b>A:</b> First up is Robert Farra, president & COO of
MicroCHIPS (the company you mentioned in your opening). Robert’s product
experience covers drug delivery combination products, implantable
glucose sensors, life support systems, ventricle assist devices,
artificial hearts, intra-aortic balloons and pumps, minimally invasive
laparoscopic, and endoscopic and surgical devices, as well as capital
equipment and their corresponding single-use devices.<br />
<br />
Next up is Paul Gerrish, senior director, technology and design, implantable microsystems technology, <a href="http://www.medtronic.com/">Medtronic</a>.
What impressed me is that his bio includes a statement that Medtronic’s
Implantable organization is “energized by the belief that there is
still tremendous opportunity for hardware solutions to contribute toward
making a difference in improving the lives of people worldwide.” I love
it.<br />
<br />
And last but definitely not least is someone from your hometown of Pittsburgh: Ivo Stivoric, CTO & VP of new products, <a href="http://www.bodymedia.com/">BodyMedia</a>.
As one of the original founders, he took his vision for the
life-changing BodyMedia technology from conception to launch, first in
the medical space and then to consumers. Today Ivo is spearheading the
rapid expansion of the product line across a wide-range of healthcare
applications such as disease management.<br />
<br />
<b>Q: Wow, that <i>is</i> an impressive panel! You will have
your hands full moderating the discussion but I am confident that you
are up to the task. Let’s talk about some of the issues that you’re
going to discuss with the panelists. For example, how is MEMS enabling
better health/QoL with regard to prevention, monitoring, management,
rehab, and replacement?</b><br />
<br />
<b>A:</b> MEMS continues to play a critical role in the
development of new technologies that assist with patient monitoring,
diagnostics, therapy and portable health care. Chronic diseases are an
epidemic. It is possible to delay or prevent many chronic diseases
associated with obesity and aging by remaining physically active. An
activity monitor, for example, is a small device that records
information about user’s physical activity patterns throughout the day.
MEMS inertial sensors form the basis of many activity monitors that are
designed to detect changes in force resulting from motion, tilt,
positioning, shock and vibration.<br />
<br />
Another possible side effect of aging and obesity is hypertension.
MEMS pressure sensors enable the use of blood pressure monitoring
conducted at home for the diagnosis and management of hypertension.
Inertial sensors are also used to improve QoL for rehab and replacement.
Inertial measurements provide motion tracking, posture and gait
analysis to help daily movement and flexibility and to enhance athletic
performance.<br />
<br />
<b>Q: What are your thoughts on where we will be in the next 5-10 years, in terms of MEMS advancing applications in medical/QoL?</b><br />
<br />
<b>A:</b> Research is currently underway using MEMS
technology for many innovative applications such as artificial pancreas,
human-like motion for prosthetics, sensor arrays for rapid monitoring
and diagnosis at home, and micropumps for drug delivery. MEMS pressure
sensors will be used more frequently in invasive medical applications
such as catheter tip sensors. While not all of these solutions will be
in widespread use due to the rigorous testing required for medical
devices, the trend toward using MEMS in health and medical applications
will continue to enhance QoL.<br />
<br />
<b>Q: We are seeing a lot about how people are utilizing
existing consumer devices (such as smartphones) to monitor their health.
What are some examples of how they being adapted for QoL applications?</b><br />
<br />
<b>A:</b> Existing medical applications such as telehealth
gateways are becoming more connected. Telehealth gateways are data
aggregators that tie various MEMS sensor solutions with back-end personal health records (PHR) via the cloud. Consumer devices containing
MEMS sensors such as smartphones, pedometers, and other activity
monitors can monitor activity and then transmit data to the cloud for
use by physicians and patients.<br />
<br />
As MEMS devices become integrated into healthcare applications,
contextual awareness applications become more feasible. Augmented
reality applications such as a ‘virtual nurse,’ will allow intuitive and
rich interactivity between a patient and their environment and a
patient and their medical support team -- all in support of improving
QoL.<br />
<div align="left">
<br /></div>
<div align="left">
<i>Thank you Jeannette. I am really looking forward to
hearing more about MEMS enabling health and QoL at the MEMS Executive
Congress US 2012 in Scottsdale (your neighborhood) in November!</i></div>
MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-80726042480600217852012-08-30T11:55:00.000-07:002012-08-30T11:55:36.613-07:00MEMS Product Development Challenges – Sweet Dreams and NightmaresMEMS product development is not for the faint of heart. Though you
will see many success stories in the industry, you will also see many
failed ventures (did anyone say “telecom bubble?”), several bankruptcies
(TeraVicta to name one), gray hair (or no hair), and divorces (sad, but
true). And then there are the companies that are just middling along,
waiting to break through – we have a duty to help them break out – <em> now</em>!<br />
<br />
That’s why I aptly titled our upcoming 2<sup>nd</sup> annual MEMS Industry Group (MIG) workshop with BSAC, on September 19, “<a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=4150&utm_source=html&utm_medium=email&utm_content=september-events&utm_campaign=mig-hh-bsac">MEMS Product Development Challenges – Sweet Dreams and Nightmares</a>.”
We have a lot to be proud of in the MEMS industry, but we still have a
lot to learn and a lot to improve on in order to grow. We may be a
$10B/year industry now; but to get to my dream of “MEMS frickin’
everywhere,” we need to do more.<br />
<br />
All year long, MIG’s theme for content and programs has been focused
on addressing MEMS product development and commercialization challenges.
Our annual technical members meeting, <a href="http://www.eiseverywhere.com/ehome/index.php?eventid=34492">M2M Forum</a>, focused on MEMS new product development and we invited Len Sheynblat of Qualcomm to give a <a href="http://www.memsindustrygroup.org/i4a/doclibrary/index.cfm#category_31">keynote</a>
on the real truth about what makes integrating MEMS and sensors into
end-use mobile devices so darned hard and complicated: a lack of MEMS
standardization. We teased out the differences and nuances between MEMS
technology push and market pull; when, what and how it matters and why
we should care. We developed a MEMS Technology Development Process
Template to help managers navigate the gating process to determine when
and if a MEMS device is a GO or NO GO. Additionally, MIG has worked
closely with our <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=4155">MIG Technical Advisory Committee (TAC)</a> to ensure the content of our <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=3446">MEMS Education Series webinars</a> is focused on MEMS product development.<br />
<br />
We also hosted a fantastic one-day pre-conference symposium at <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4121">Sensors Expo & Conference</a>
in June – all focused on, you guessed it – MEMS commercialization
challenges. This time we called it “MEMS in the Mainstream:
Commercialization and Product Realization – Leveraging the MEMS
Infrastructure” (I was feeling less creative that day, I guess). I am
really proud of the folks we invited to speak and present at the Sensors
Expo pre-con and MEMS tracks. The presenters all spoke honestly about
the sweet dreams and nightmares they experienced while taking a MEMS
device through the many stages of development along the MEMS supply
chain. Thankfully, the supply chain is a heck of a lot more robust to
help shift the odds more towards the “sweet dreams” side of things
rather than the nightmares…but it’s still critical to keep that honest
conversation going and give those case studies about MEMS product
development challenges, specifically about MEMS fabrication models.<br />
<br />
That is why our September 19 workshop at BSAC is so unique. We will
give attendees an inside peek at how some of the best and most
impressive MEMS companies have overcome their nightmares and are
enjoying some sweet dreams (with occasional scary monsters under the bed
and in the closet at times, I am sure). I am thrilled that one of MIG’s
Governing Council members, and a really nice guy, the esteemed <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#DaveJ.Monk">Dave Monk</a>,
MEMS Automotive Sensor Product Manager, Freescale Semiconductor, will
present a case study on Freescale’s hybrid model of fabrication: “<a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/abstract.php?iab=1332970930&d=1348038000&t=1348074900">To Integrate or Not to Integrate: A Case Study on System-in-Package Integration for MEMS-based Products.”</a><br />
<br />
This workshop is <em>especially</em> unique – because for the first
time – drum roll please – we will have Knowles Electronics share a case
study on their perspective of having a totally fabless model for their
MEMS microphones. This is big stuff people. I didn’t have to change the
name of my first born to get Knowles to agree to come and present; but
it did take some convincing so I hope you will join me to hear <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#AngeloAssimakopoulos">Angelo Assimakopoulos</a> Director,
New Business Development and his colleague, Eric Lautenschlager, MEMS
Engineer Manager, talk about how the magic happens. The third case study
will be given by my friend and colleague, <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#PeterHimes">Peter Himes</a>,
VP Marketing of Silex Microsystems, the worlds’ biggest pure play MEMS
foundry (I feel like have been programmed to say that every time I say
the word “Silex”). Peter has been working on this presentation all
summer – “<a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/abstract.php?iab=1332970930&d=1348038000&t=1348078500">Foundry:
MEMS Product Proliferation and Time to Market: A Foundry’s Perspective
on Process Standardization vs. Full Customization</a>” - and I can’t wait to see it (especially the part with the Swedish chef – right, Pete?).<br />
<br />
After the case studies we’ll allow for a very short break and then the fun will begin again. <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#LeslieField">Leslie Field</a>,
Consultant, Manager and Founder, Small Tech Consulting will moderate
the panel “Successful MEMS Commercialization – Lessons Learned.”
Panelists include MIG members <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#Dr.EvgeniGusev"> </a><a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#EvgeniGusev">Evgeni Gusev</a> Sr. Director Technology R&D, Qualcomm MEMS Technologies; and <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#MarcellinoGemelli">Marcellino Gemelli</a>, Senior Marketing Manager, Bosch Sensortec; and BSAC spin-outs <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#ChristineChihfanHo">Christine Chihfan Ho</a> CTO, Imprint Energy; and <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=2#OctavianFlorescu">Octavian Florescu</a> President,
Silicon BioDevices. These four bring very diverse backgrounds and
perspectives on what it takes to successfully navigate the
commercialization process, including considerations for planning the
development of new products. I look forward to hearing how each of them
will define “successful commercialization” and how they address the
challenges of integrating MEMS into existing applications vs. new
products. I also think it will be fun to hear what questions the
audience will ask…<br />
<br />
I encourage you to join me on September 19 on the UC Berkeley campus – for the workshop, our <a href="http://www-bsac.eecs.berkeley.edu/events/8667029069/?m=1">joint session</a> in the afternoon with BSAC, and finally our mixer/social/cocktail party in the evening (sponsored by <a href="http://www.classoneequipment.com/">ClassOne Equipment</a> – thanks guys!). The early bird registration discount ends on September 6 – so don’t delay! The time for MEMS really <em>is</em> now.<br />
<br />
And, if you’re a MIG member, start the party early in Mountain View on September 18 at a Happy Hour we are hosting at <a href="http://tiedhouse.com/">Tied House Brewery & Café</a>, sponsored by one of our distinguished industry partners <a href="http://www.mipi.org/">MIPI Alliance</a>. <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageid=4150&utm_source=html&utm_medium=email&utm_content=september-events&utm_campaign=mig-hh-bsac">RSVP</a> today!MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com1tag:blogger.com,1999:blog-8502013452232912014.post-20186549242372927292012-08-16T11:19:00.000-07:002012-08-16T12:19:58.443-07:00A Visit to GE Global Research, Niskayuna, NYPerched on a bluff overlooking the Mohawk River in Niskayuna, NY is a powerhouse of industrial R&D; <a href="http://ge.geglobalresearch.com/locations/niskayuna-ny-usa/" target="_blank">GE's Global Research Center</a> (GRC). GRC just celebrated its 110 year anniversary. Thomas Edison's original desk is on display in the entry lobby to prove this point! <br />
<br />
(Click on any of the images below to enlarge them.)<br />
<br />
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The Niskayuna facility is the largest of several GRCs. GE also has centers in Munich, Germany; Bangalore, India; Shanghai, China; Rio de Janeiro, Brazil and San Ramon, California. <br />
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The history of invention and innovation that has taken place at GRC to create major new businesses was on display as we walked along the entry hall. Some highlighted examples include x-ray medical imaging, jet engines, magnetic resonance imagers, digital x-ray panels and a number of other world firsts. The Research Center in Niskayuna is one of the world's largest corporate R&D centers that conducts focused, strategic research and development. This is GE -- after all -- and GE has the demonstrated ability to identify new business opportunities, utilize its research capacity to develop the required technologies in collaboration with GE businesses, and then to grow these businesses globally. As such, the master plan needs significant R&D capability to back it up.<br />
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The GRC R&D programs are divided between longer term projects (Advanced Technology programs) and projects that develop technology for one or more GE products in a two to five year time frame. GE business divisions (i.e. GE Aviation, Healthcare, Energy, Oil and Gas, etc.) fund the shorter term, targeted R&D projects and researchers at the Center therefore have an internal business customer. GRC is responsible for meeting the needs of that business, and the businesses frequently visit the Center to review technical progress. <br />
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GRC has been conducting research in MEMS since 2002. The objective of this research is to create new MEMS components that are not commercially available and that enable a breakthrough feature or strengthen the value proposition of a GE product. One of the most impressive MEMS devices that I learned about at GRC is a MEMS microswitch -- GRC researchers claim this switch to be the fastest switch that acts as a mechanical relay (vs. solid state, semiconductor switches). Through applied and focused R&D, the brilliant scientists at GRC have created a MEMS microswitch that handles over a kilowatt of power (240 Volts AC and 7 Amps). For its industrial applications (just for starters) this MEMS microswitch reduces the time required to interrupt a fault current (short circuit) from milliseconds (the switching speed of conventional circuit breakers) to a few microseconds (for a breaker made from MEMS switches). <br />
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It is equally amazing that these researchers were able to utilize a novel set of materials to construct the MEMS switches (GRC's "secret sauce"). The switch materials and the process flow are compatible with both silicon and quartz substrates, and it may be possible to fabricate these switches on completed CMOS wafers. The novel materials play a key role in enabling the fabrication of the robust, reliable and mega-power-conveying MEMS microswitches. In addition, GRC also does all the failure mode analysis, reliability testing, and most of the packaging for the microswitches; as well as most of the other MEMS they R&D and fab onsite. It's quite an impressive operation.<br />
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Chris Keimel of GRC presented an abstract on the MEMS microswitch at <a href="http://www.hh2012.org/program/HH2012_FinalProgram.pdf">Hilton Head</a> Workshops in June 2012. His paper created a lot of buzz; and as more folks learn about it I am confident that the buzz will turn into a loud roar of applause (maybe this blog will help; I can only humbly hope so!).<br />
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Beyond the research being done at universities and research institutes in the US and abroad, I can think of only one other example (in the MEMS field) of a company doing this level of sophisticated commercialization-focused research; Robert Bosch GmbH (and they are privately-held; GE is not). <br />
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But what makes GRC unique is that for MEMS, not only do these guys do the R&D at GRC, they also do the pilot volume fabrication. With their new expanded cleanroom facility (nearly 30,000 sq. ft.); they are doing amazingly cool stuff in MEMS. From what I learned on the full head-to-toe bunny suit tour that I had with fab manager, Ron Olson, GRC is fabricating both silicon carbide based power MOSFETs and MEMS for GE at an impressive rate. By no means is this a high-volume fab; but these guys have a sophisticated operation that is able to accommodate both the R&D and the pilot volume needs of GE's businesses in a single facility. <br />
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Lastly, no visit to the facility can be complete without a mention of the beauty of the place. It truly is gorgeous, especially in July (maybe a bit cold in January?). The rate of turnover at GRC is low and I can see why; why would you want to leave this place? You get to work with brilliant scientists, doing great commercially focused R&D, actually manufacture products and live in a beautiful part of the country. As Thomas Edison once stated: "I never perfected an invention that I did not think about in terms of the service it might give to others." Clearly at GRC Niskayuna, his legacy lives on. MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-37562708929777432102012-07-23T08:38:00.001-07:002012-07-23T13:34:12.933-07:00SEMICON West 2012: Where Has the Love Gone?Has the romance between the MEMS and semiconductor industries started to fizzle? Or is the real issue that for new equipment vendors, the appeal and shiny/sexy new-ness of MEMS has faded as they salivate in anticipation of a switch from 300 to 450mm (with all of that sexy, new and expensive semiconductor equipment)?<br />
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In 2011, I declared that it was the "<a href="http://memsblog.wordpress.com/2011/07/14/karen%E2%80%99s-blog-from-semicon-west-2011-%E2%80%93-it%E2%80%99s-showtime/">the year of MEMS</a>" at SEMICON West in my MEMSblog, because last year, MEMS was everywhere! This year, not so much...<br />
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Don't get me wrong; I love going to SEMICON West. I keep coming back because it's like homecoming. I can't walk the halls of Moscone without bumping into dozens of colleagues and MEMS Industry Group (MIG) members. This year it was even more fun, because I was armed with hundreds of adorable <a href="http://www.flickr.com/photos/50603106@N08/7604365594/">MIG stickers</a> that I emblazoned/bedazzled on every MIG member (and future member) I saw.<br />
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<span id="more-2255"></span>MEMS was definitely present at SEMICON West this year, and the MIG brand was stronger than ever. MIG had a fabulous MEMS Pavilion, with co-exhibitors IMT, IQE Silicon, n&k Technology, Oxford Instruments, and Xactix. The MIG member lounge inside the pavilion was always full of activity (and fun). The MEMS content on the first day -- which I had the honor of moderating -- "<a href="http://www.semiconwest.org/node/8496"><b>Taking MEMS to the Next Level: Transitioning to a Profitable High Volume Business</b></a>" -- was chock full of MIG member companies: Applied Materials, Coventor, Hillcrest Labs, NIST, Silex, Teledyne DALSA and Yole Developpement. <br />
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And I must humbly add that MIG's fifth annual member happy hour at LuLu's was THE BEST frickin' party at SEMICON West this year. Our party was rockin' and we have the <a href="http://www.flickr.com/photos/50603106@N08/sets/72157630623015886/">Flickr photos</a> to prove it. No need for caution in case you were worried: the photos are all clean and involve no mechanical bulls (pause for the inside joke). It was the best party I attended, and if you think your party was better then you better invite me to <i>your</i> party next year so I can be the judge!<br />
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But, sadly, here's where I must address the feeling I had during SEMICON West that "the love is gone." Much of the content presented at the off-site conferences and workshops I attended had little or no mention of MEMS. And while the underlying reasons may be otherwise, I do wonder, in my heart of hearts, if the growing disconnect between MEMS and the semiconductor industry stems from the latter's embrace of the migration to 450mm.<br />
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To the delight of those who want to enter MEMS manufacturing -- or for those who want to stay there -- the move to 450mm is in no way a requirement. Companies can manufacture MEMS devices on 200mm wafers just fine, thank you. Does this explain why only a handful of stalwart MEMS device manufacturers were present? Is the zeal for 450mm on behalf of semiconductor equipment vendors (who dominate SEMICON West) responsible for the seemingly fair-weathered friendship between MEMS and the semiconductor industry at SEMICON West or is it an issue worldwide? <b>Share your thoughts with me -- and let's keep this discussion going.</b><br />
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Email Karen Lightman at <a href="mailto:klightman@memsindustrygroup.org">klightman@memsindustrygroup.org</a>MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-30655937837850147872012-07-12T11:25:00.004-07:002012-07-23T07:59:47.989-07:00Sensors Expo report: MEMS Pre-Conference Symposium<i>MEMS in the mainstream -- Music to my ears</i><br />
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For the second year in a row, MEMS Industry Group was host to the Sensors Expo Pre-Conference Symposium, and this year's theme was "MEMS in the Mainstream: Commercialization and Product Realization -- Leveraging the MEMS Infrastructure." I felt like a bandmaster -- not trying to make the music, just trying to get the band with all its different instruments, rhythms, and tones to harmonize.<br />
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It's not a simple piece to orchestrate, because when you talk about commercialization and product realization and leveraging the <a href="http://www.electroiq.com/mems.html">micro electro mechanical systems (MEMS)</a> infrastructure, you are talking about lots of different perspectives from equipment vendors to materials suppliers, from foundries to device manufacturers (some captive-fab, some fab-lite, some fabless), as well as from end-users and OEMs. Each of these "bands" has its own instrument, its own sheet music, its own style and its own "special sauce." You can see where I am going with this analogy. Like in music, MEMS can either work like a 10-piece orchestra in total sync and harmony, or it can sound like something the cat dragged in!<br />
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Thankfully, at our Sensors Expo pre-conference, we sounded a lot more like the 10-piece orchestra. We focused on utilizing the MEMS infrastructure to produce harmonious communication with our customer and our customer's customers, in order to get the product out in time, at cost, and in the right form factor.<br />
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Each of our presenters and panelists shared their own perspectives. They didn't always agree (oftentimes they didn't) and that's OKAY -- because MEMS by its nature is not one-size-fits-all. Approaching the topic of MEMS foundry models from differing angles, John Chong of Kionix and Rob O'Reilly of Analog Devices Inc. (ADI) both gave fantastic overviews of MEMS foundry models, digging into which approaches work for them and why.<br />
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IMT's Craig Trautman and Silex's Peter Himes carried the foundry discussion a little further. As foundry companies, they were able to rise above the idea that everyone should go fabless, in support of the diversity and maturity of the MEMS industry. I think Craig summed it up well when he said: "There's no free lunch. There are pros and cons for various models of MEMS fabrication: fabless vs. captive). As a foundry, we have five customers 'living' at IMT. We give them free office space because a lot of the things that we do are really hard. The customer needs to collaborate to make it all work."<br />
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I loved hearing from the end-users, and those working closest to the end-users as these are the people who are truly driving the market for MEMS (and our future). As eloquently stated by Jim Clardy of Dell, "I want to avoid end-user scenarios where people have to wave a tablet around to get magnetometer calibrated. Sensors are collecting ambient data. What are the privacy and security concerns? Data must be shared with the cloud. Someone must track the user, his/her location, etc. Whoever controls those ecosystems is going to know A LOT about the end-user. This could be an adoption barrier."<br />
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We in the MEMS industry really need to listen to folks like Jim! We need to be thinking about the sensor fusion of all of these sensors; the security of that data; and the human who is interfacing with the device. We need to remember that MEMS is just an instrument. Sitting by itself untouched, it is nothing. But when it's played by the right artist, placed in the right band, it can harmonize and make beautiful music. And yes, that is music to my ears.<br />
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Contact Karen Lightman, managing director of MEMS Industry Group at <a href="mailto:klightman@memsindustrygroup.org">klightman@memsindustrygroup.org</a>MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-35403106362664226652012-07-12T11:24:00.003-07:002012-07-16T09:31:05.459-07:00MEMS isn't NEWWhat do you think of when I say the words "MEMS new product development?" Do you envision new categories of newly discovered MEMS hatching somewhere in a university lab? If your answer is "yes," perhaps you should rethink that -- because MEMS isn't new. If we are to grow this $9 billion/year industry to a hundred-billion or even trillion dollar industry as some predict, we need to think of <i>new</i> MEMS in terms of how the "regular, everyday" MEMS we have right now are used in development of new end products. Whether these new MEMS-enabled products come from a combination of market pull and/or technology push, there are challenges and hurdles that the industry must come together to address, now!<br />
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That is why we focused the MEMS Industry Group (MIG) <a href="http://www.memsindustrygroup.org/m2m">Member-to-Member (M2M) Forum</a> on MEMS "New Product Development" earlier in May -- because it is so time-critical for the MEMS industry to come together and address these barriers and challenges to commercialization that are hindering growth. Barriers that I like to call the "stickiness of MEMS," which include the "S" word of MEMS -- "Standards" for things such as testing, packaging...not the sexy, shiny, bright things that are hatched in the lab and then probably never make it to the market.<br />
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I invited <a href="http://www.eiseverywhere.com/ehome/34492/56974/#len">Len Sheynblat</a> of Qualcomm CDMA Technologies (QCT) to give the keynote, "Sensor Systems Integration Challenges," which spelled out in very specific terms what the MEMS industry needs to do, specifically, Sensor API Standardization. He shared QCT's commonly requested sensor vendors: 18+! With 26+ sensor product lines! And on top of this, there are numerous handset and tablet OEMS with different ecosystems: Android, Windows, RIM (which used to be Palm), etc. They all want to be loved, and this makes developing with MEMS just a smidge complex.<br />
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Sounds a bit nightmarish, don't you think? I sure do, and MIG will be working with our members and strategic partners, including the MIPI Alliance, to address these challenges and issues of the stickiness of MEMS. I urge you to contact me and become active and involved in our M2M Action Item Task Forces.<br />
That's also why the MIG Technology Advisory Committee (MIG TAC) chose Mary Ann Maher, CEO of SoftMEMS, as the winner of our first-ever white paper competition, because she discussed the important issue of co-design and yes, standards. And because Mary Ann was the evening speaker, she also made the presentation into a drinking game. (Every time she said "co-design," you were to take a sip; I gave up after the 15th time.)<br />
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And as we have every year, since MIG began with DARPA funding, we also had working groups to dive deeper into the conference topic. Our working group leaders (Jim Knutti of Acuity, Mike Mignardi of TI, Jason Tauscher of MicroVision and Valerie Marty of HP) did a fantastic job of moderating the rich discussions we had in the working group breakout groups on "<a href="http://www.eiseverywhere.com/ehome/34492/56974/#wg2">Market Pull vs. Technology Push</a>" and "<a href="http://www.eiseverywhere.com/ehome/34492/56974/#wg1">MEMS Technology Development</a>." I encourage you to check out the MIG resource library to see the body of knowledge and case studies we've gathered; and MIG action item task forces will be forming soon to carry out several of the recommendations.<br />
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M2M Forum also featured a panel of speakers expressing diverse opinions and perspectives on new product commercialization -- from those involved heavily and not so heavily with MEMS. The panel included: Anne Schneiderman of Harris Beach, an expert in IP law; Stefan Finkbeiner, a MEMS device manufacturing veteran with Bosch/Akustica; Matt Apanius with SMART Commercialization Center for Microsystems, who is well versed in tech transfer from lab to fab; and Ivo Stivoric with BodyMedia, someone who embodies a MEMS supplier's dream of an end-user company.<br />
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My favorite part of the panel was when Ivo described the challenges in understanding/analyzing the "white space in the market." He warned that as a consumer of MEMS, he oftentimes doesn't need a new device; he just needs a tweak or two and then wants the device manufacturer to "just go away" so he can go back to his customers. Amen, brother. I want that for you, too. Because the truth is that MEMS isn't new, and so we need to find the solutions to these challenges to commercialization, and then move on to conquer the other white space in the market.<br />
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Contact Karen Lightman, managing director of MEMS Industry Group at <a href="mailto:klightman@memsindustrygroup.org" title="blocked::mailto:klightman@memsindustrygroup.org">klightman@memsindustrygroup.org</a>MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0tag:blogger.com,1999:blog-8502013452232912014.post-53881848174613464052012-07-12T11:23:00.002-07:002012-07-16T09:35:24.389-07:00Conference Report: MEMS Executive Congress EuropeST's Carmelo Papa boldly declared that "MEMS is only limited by the imagination" during his opening keynote at <a href="http://www.memscongress.com/europe" target="_blank">MEMS Executive Congress Europe</a>. In many ways this phrase exemplifies the conference itself. All of the speakers on our four panels -- industrial, biomedical/Quality of Life (QoL), automotive and consumer -- as well as our keynotes -- conveyed that frontier feeling that MEMS can truly change the world. Sure we have some challenges to overcome (the biggest being packaging), but the potential of having MEMS (frickin') everywhere is a very tangible reality.<br />
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Thankfully the media who attended the Congress Europe have already done an impressive job of highlighting the panelists' and keynotes' more technical points. (Please refer to our <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4064" target="_blank">Congress press coverage</a> for the growing list of stories.) So instead of retelling you who said what regarding which ISO qualification, I'll use this blog to give you the more colorful side of the Congress (shocking disclosure, I know). And speaking of color, MIG's Monica Takacs did a great job of capturing the Congress in pictures and we've posted them on our <a href="http://www.flickr.com/photos/50603106@N08/sets/72157629634368307/" target="_blank">Flickr site</a>; you will want to check it out.<br />
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I am going to give you a taste of the Congress by sharing with you my favorite quotes, saving my very favorite for last. I'll start with one by our opening keynote, <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4003#papa" target="_blank">Carmelo Papa</a>. When Carmelo was talking "off the ST script," his playful Italian personality made him a crowd favorite. Like when he said that he couldn't reveal ST's biggest customer "even under torture," but he'd give us some hints: "It is green, round and delicious to eat." What a great way to describe Apple. I also liked how he described MEMS as the "mouse for portable devices" as it enables a new realm of gesture.<br />
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My next favorite quote was from VTI's <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4003#Laatikainen" target="_blank">Hannu Laatikainen</a>. I began to think of him as a "Finnish Haiku Poet" when he said that we needed to "treat the car more like a human that can see, feel, hear, smell and taste." Great stuff. I absolutely enjoyed hearing every single word coming out of the mouth of <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4003#berger" target="_blank">Dr. Berger</a> of Clinatec and it wasn't just because I am a sucker for a French accent. I loved his description of connecting technology with medicine and his passion for patient health, safety and welfare. He urged that there must be more money for clinical trials of technology for medical treatment to prove efficacy (not just money for consumer-inspired sport applications masking as healthcare products). I couldn't agree more.<br />
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I laughed when <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4003#finkbeiner" target="_blank">Stefan Finkbeiner</a> introduced himself and stated that his company, Akustica, hailed from Pittsburgh, the "MEMS center of the US." Stefan then modified the statement by saying that Pittsburgh is the "MEMS capital of Pennsylvania" and "definitely the MEMS capital of Western PA." My hometown is <i>a lot </i>of things, but not <i>yet</i> the MEMS capital of the US.<br />
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But my absolute favorite quote from MEMS Executive Congress Europe came from Continental's <a href="http://www.memsindustrygroup.org/i4a/pages/index.cfm?pageID=4003#schmid" target="_blank">Bernhard Schmid</a>. When someone from the audience asked the panelists if visual sensors will replace MEMS on automotive, Bernhard responded with a rhetorical question: "Have the eyes cannibalized the ears? No. Both senses/sensors are needed for smart automotive." I guess he was inspired by Hannu's earlier comment about the car's senses being more human. I wouldn't have expected such eloquence from a bunch of automotive engineering executives. But like the Congress in general, these guys impressed and surprised me.<br />
MEMS Executive Congress Europe was a fantastic success. I was expecting 100 attendees; we had 155. I thought we had a handful of sponsors; we had over 30.<br />
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While pausing momentarily to reflect on the highlights of our European event, my staff and I are looking forward to building the content for this year's upcoming MEMS Executive Congress US in Scottsdale (November 7-8). And yes, we are looking at another Congress event in Europe in 2013 and possibly in Asia as well.<br />
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By design, MEMS Executive Congress is unique in the industry. Involving only minimal bribery (just the chocolate in Zurich at our European event!), we have been fortunate to engage MEMS suppliers and their end-user customers in thoughtful, sometimes spirited discussions about the use of MEMS in commercial applications. With our success in both the US and now in Europe, MIG is meeting a need in the market. Good thing it's also lots of fun.<br />
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<em>-- </em>Karen Lightman, Managing Director of the MEMS Industry Group.MEMSBloghttp://www.blogger.com/profile/11255761933466539973noreply@blogger.com0