Smart Mobility Architecture

Computer form factors
Listed by PCB size (mm)
WTX (356×425) AT (350×305) Baby-AT (330×216) BTX (325×267) ATX (305×244) SSI CEB (305x267) EATX (Extended) (305×330) LPX (330×229) microBTX (264×267) NLX (254×228) Ultra ATX (367×244) microATX (244×244) DTX (203×244) FlexATX (229×191) Mini-DTX (203×170) EBX (203×146) Mini-ITX (170×170) EPIC (Express) (165×115) Mini ATX (150×150) ESM (149×71) Mini-STX (140×147) Nano-ITX (120×120) COM Express (125×95) ESMexpress (125×95) ETX (114×95) XTX (114×95) Pico-ITX (100×72) PC/104 (-Plus) (96×90) ESMini (95×55) SMARC (82×80) Qseven (70×70) EOMA-68 (86x54) mobile-ITX (60×60) CoreExpress (58×65)

SMARC (‘Smart Mobility ARChitecture’) is a specification published by the Standardization Group for Embedded Technologies e.V. (SGET) for computer-on-modules (COMs).^[1] SMARC Computer-on-Modules are specifically designed for the development of extremely compact low-power systems. Generally, SMARC modules are based on ARM processors, they can, however, also be fitted with other low-power SoC architectures, like, for example, ones based on x86 SoCs.^[2] Typically, SMARC modules’ power requirement is in the range of a few watts, which opens up avenues to markets which to date could not be addressed due to processor designs with much higher power consumption.^[3]

Computer-on-Modules integrate the core function of a bootable computer, like SoC, as well as additional circuitry, including DRAM, boot-flash, voltage distribution, Ethernet and display transmitter. The modules are deployed together with an application-specific carrierboard, whose size and form can be defined to meet customer-specific requirements. The carrierboard executes the required interfaces and can integrate, if required, any further functionalities, such as audio codecs, touch controller, wireless communication interfaces, etc.

The SMARC specification outlines both the dimensions of the module and the positioning of the anchor points as well as the connector to the carrierboard and, most importantly, the executed interfaces with the pin-out. The pin-out is optimized for ARM and low-power SoC interfaces and is distinguished from classical PC interfaces by its target-oriented focus on low-power and mobile applications.

SMARC is based on the ULP-COM form factor^[4] which was introduced by the companies Kontron and Adlink in 2011. During the specification process by the SGET the standard was renamed to SMARC.

Dimensions

SMARC defines two module sizes:

82 mm × 50 mm for extremely compact low-power designs
82 mm × 80 mm for SoCs with higher performance and with increased space and cooling requirement

Connector

SMARC Computer-on-Modules have 314 card edge contacts on the printed circuit board (PCB) of the module which is plugged via a low-profile connector on the carrierboard. In most cases, the connector has a construction height of 4.3 mm. It is also used for MXM 3.0 graphic cards, which naturally have completely different pin assignments.

Signal lines and pin assignments

Signal transmission is carried out via a total of 314 pins. 33 of these are reserved signal lines for power supply and grounding, so that with SMARC a total of 281 signal lines are effectively available. ARM- and SoC-typical energy-saving interfaces, like, for instance, parallel LCD for display connection, mobile industry processor interfaces for cameras, Serial Peripheral Interface (SPI) for general peripheral connection, I²S for audio and I2C are included. Besides these, classical computer interfaces such as USB, SATA and PCI Express are also defined.

In the current version of the SMARC specification not all of the 314 signal lines are assigned to fixed I/Os. The Alternate Function Block (AFB) has free pins available for different requirements. This is to ensure that the SMARC specification can flexibly accommodate up and coming technical developments which today are not foreseeable while remaining fully compatibility to previous designs. On the one hand, extended versions of the SMARC specification can assign new standard functions to these 20 AFB signal lines. On the other hand, the SMARC specification 1.0 currently lists the MOST (Media Oriented System Transport) bus, Dual Gigabit Ethernet, Super Speed USB, or industrial network protocols which from a current point of view could be imagined as or might be assigned as interfaces of the AFB.

Specification

The SMARC hardware specification V1.0 is supervised by the SGET. The specification is freely available as a download on the SGET website.

References

External links

This article is issued from Wikipedia - version of the 6/8/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.