Continuing discussion on Kinetis MCU family - Security is a keen feature there as well - in add'n to the AFE application specific nature of the K50. The Kinetis family offers these security features:
Hardware Random Number generator, Memory Protection Unit, Protected Flash Memory, Encrypted communication capability, Hardware Cryptographic acceleration, Unique chip identifier, Secure Key storage/Chip ID, Tamper detection/Secure RTC, and more -
Adding to the MCU discussion from earlier.. RE: MPU, Freescale is finding great success in it's i.MX product line as well - our multimedia processors. These are being used in various applications such as:
i.MX27/28 - Home Health Hubs
i.MX51/53/6X - Multiparameter patient monitors, EKG/ECG, Infusion Pump and Ultrasound
The i.MX product family (similar to that of Kinetis MCU) has some significant benefits in cost/performance - as well as Security features that make it a winner. Google i.MX and Trust Architecture.
Check out www.freescale.com/medical for application-specific block diagrams and schematics, design resources - including the Medical Applications Guide, videos, webcasts and more. Interact with us on the Medical By Design blog. Follow us on Twitter, LinkedIn and Facebook.
Re: Personalized Medicine example. My example of Dexcom (CGM) and Insulet OmniPod (Insulin Delivery) is one really good example of personalized medicine. Together they create the equivalent of an artificial pancreas... Pretty personal.
MCU's of interest include those based on ARM core technology - more so today than a year ago. The Kinetis K50 for example is a based on the 32bit ARM Corext M4 and employs a great analog front end designed specifically for Blood Glucose Metering for example.
Could be a long answer. Cancer therapy is one such dosing app. Measuring actual dose and immediate are is key. More prevalent? Again hard to say exactly but another is Drug/Device interaction and leveraging more device in the drug delivery.
Thanks for your answer about implantable materials to enclose electronics. I realize you may not be a materials expert. However, I was surprised that you mentioned titanium, but not implantable plastics, of which there are many. For example, polyethylenes, PEEK, and various composites in things like artificial spinal disks and bone anchors. Do you see an increase in use of these and other plastics for implantablre devices?
Great discussion. The healthcare industry has talked for several years about mobile health monitors, but product introduction and more importantly, acceptance and use have been slow. What has changed recently to make you beleive that this portable/mobile part of the segment is now poised for growth? follow on - Are new standards needed to accelerate this growth?
Earlier this year paralyzed IndyCar drive Sam Schmidt did the seemingly impossible -- opening the qualifying rounds at Indy by driving a modified Corvette C7 Stingray around the Indianapolis Motor Speedway.
Wearables are changing the way we see ourselves. With onboard sensors that have access to our bodies, we are starting to know our physical selves like never before, quantifying our activity, our heart rate, breathing, and even our muscle effort.
Last week, the bill for reforming chemical regulation, the TSCA Modernization Act of 2015, passed the House. If it or a similar bill becomes law, the effects on cost and availability of adhesives and plastics incorporating these substances are not yet clear.
This year, Design News is getting a head start on the Fourth of July celebration. In honor of our country and its legacy of engineering innovation -- in all of its forms -- we are taking you on an alphabetical tour through all 50 states to showcase interesting engineering breakthroughs and historically significant events.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies. You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived. So if you can't attend live, attend at your convenience.