ATmegaS64M1 MCU allows customers to begin development with a commercial device before moving to a pin-out compatible, qualified radiation-tolerant version
19 December 2017, New Delhi, [NASDAQ: MCHP] — Developing radiation-hardened systems for space applications has a history of long lead times and high costs to achieve the highest level of reliability for multi-year missions in a harsh environment. Today, NewSpace and other critical aerospace applications require faster development and reduced costs. To meet these needs, a new microcontroller (MCU) that combines specified radiation performance with low-cost development associated with Commercial Off-The-Shelf (COTS) devices is now available from Microchip Technology Inc.
The ATmegaS64M1 is the second 8-bit megaAVR® MCU from Microchip that uses a development approach called COTS-to-radiation-tolerant. This approach takes a proven automotive-qualified device, the ATmega64M1 in this case, and creates pin-out compatible versions in both high-reliability plastic and space-grade ceramic packages. The devices are designed to meet radiation tolerances with the following targeted performances:
• Fully immune from Single-Event Latchup (SEL) up to 62 MeV.cm²/mg
• No Single-Event Functional Interrupts (SEFI) which secure memory integrity
• Accumulated Total Ionizing Dose (TID) between 20 to 50 Krad (Si)
• Single Event Upset (SEU) characterisation for all functional blocks
The new device joins the ATmegaS128, a radiation-tolerant MCU that has already been designed into several critical space missions including a Mars exploration plus a megaconstellation of several hundred Low Earth Orbit (LEO) satellites.
The ATmega64M1 COTS device, along with its full development toolchain including development kits and code configurator, can be used to begin development of hardware, firmware and software. When the final system is ready for the prototype phase or production, the COTS device can be replaced with a pin-out compatible, radiation-tolerant version in a 32-lead ceramic package (QFP32) with the same functionality as the original device. This leads to significant cost savings while also reducing development time and risk.
“Our COTS-to-radiation-tolerant approach results in a no-compromise, space-grade component and not merely an up-screened or enhanced device that’s targeted to the aerospace industry,” said Patrick Sauvage, director of Microchip’s aerospace business unit. “Developing with a COTS device that can be swapped out for a fully-functional high-rel plastic or ceramic equivalent with the same pin-out reduces development time, costs and risk for our customers.”
The ATmegaS64M1 meets the high operating temperature range of -55° C to +125° C. It is the first COTS-to-radiation-tolerant MCU to combine a Controller Area Network (CAN) bus, Digital-to-Analog Converter (DAC) and motor control capabilities. These features make it ideal for a variety of subsystems like remote terminal controllers and data handling functions for satellites, constellations, launchers or critical avionic applications. For more information visit www.microchip.com/ATmegaS64M1.
Development Support
To ease the design process and accelerate time to market, Microchip offers the STK 600 complete development board for the ATmegaS64M1, giving designers a quick start to develop code with advanced features for prototyping and testing new designs. The device is supported by Atmel Studio Integrated Development Environment (IDE) for developing, debugging and software libraries.
Availability and Packaging
The devices are available today for sampling and volume production in four derivatives:
• ATmegaS64M1-KH-E in ceramic prototype QFP32 package
• ATmegaS64M1-KH-MQ, ceramic space-grade QFP32 package, QMLQ qualified
• ATmegaS64M1-KH-SV, ceramic space-grade QFP32 package, QMLV qualified
• ATmegaS64M1-MD-HP in plastic QFP32 package, AQEC high reliability qualified for volume program
For additional information, pricing or to purchase products, contact any Microchip sales representative or authorised local distributor, or visit Microchip’s website.
Resources
High-res images available through Flickr or editorial contact (feel free to publish):
• PR graphic: www.flickr.com/photos/microchiptechnology/37951799635/sizes/l
• Chip image: www.flickr.com/photos/microchiptechnology/37951791975/sizes/l
