TMS320 explained

TMS320 is a blanket name for a series of digital signal processors (DSPs) from Texas Instruments. It was introduced on April 8, 1983, through the TMS32010 processor, which was then the fastest DSP on the market.

The processor is available in many different variants, some with fixed-point arithmetic and some with floating-point arithmetic. The TMS320 processors were fabricated on MOS integrated circuit chips, including both NMOS and CMOS variants. The floating-point DSP TMS320C3x, which exploits delayed branch logic, has as many as three delay slots.[1]

This series of processors are used as a digital signal processing co-processor and as the main CPU in some applications. Newer implementations support standard IEEE JTAG control for boundary scan and/or in-circuit debugging.

The original TMS32010 and its subsequent variants are an example of a CPU with a modified Harvard architecture, which features separate address spaces for instruction and data memory but the ability to read data values from instruction memory. The TMS32010 featured a fast multiply-and-accumulate operation useful in both DSP applications as well as transformations used in computer graphics. The graphics controller card for the Apollo Computer DN570 Workstation, released in 1985, was based on the TMS32010 and could transform 20,000 2D vectors per second.

Variants

The TMS320 architecture has been around for a while so a number of product variants have developed. The product codes used by Texas Instruments after the first TMS32010 processor have involved a series of processor named "TMS320Cabcd", where a is the main series, b the generation and cd is some custom number for a minor sub-variant.

For this reason, those working with DSPs often abbreviate a processor as "C5x" when the actual name is, for example, TMS320C5510, since all products have the name "TMS320", and all processors with "C5" in the name are code compatible and share the same basic features. Similarly, a subgrouping may be referred to as, for example, C55x, as processors in the same series and generation are even more similar.

TMS320 processors are fabricated on MOS integrated circuit chips, including both NMOS and CMOS variants.[2]

Legacy series

C2000 series

C5000 series

C6000 series

C7000 series

The C7000 series was released in early 2020, but cores are not available individually. As of August 2023, they are only available bundled inside other SOCs, such as the TDA4VM, which features a C71x DSP.

DaVinci series

OMAP variants

DA variants

DM variants

Other vendors

General Instrument manufactured the TMS32010 as a second source.

Around 1991 a CMOS-version of the TMS32020 was manufactured by ZMD under the designation U320C20FC.[10]

A number of devices from the TMS320 series are in production at NIIET Voronezh as the 1867 series,[11] including a radiation-hardened version of the TMS320C25 under the designation 1867VM7T (Russian: 1867ВМ7Т|italic=yes). Clones of the TMS320C546 went into production at PKK Milandr Moscow in 2009 under the designation 1967VC1T (Russian: 1967ВЦ1Т|italic=yes)[12] and in 2016 at MVC Nizhny Novgorod as 1910VM1T (Russian: 1910ВМ1Т|italic=yes).[13] PKK Milandr also manufactures a TMS320C54x with an additional ARM core as the 1901VC1T (Russian: 1901ВЦ1Т|italic=yes).[14]

Software support

The TMS320 series can be programmed using C, C++, and/or assembly language. Most work on the TMS320 processors is done using Texas Instruments proprietary toolchain and their integrated development environment Code Composer Studio, which includes a mini operating system called DSP/BIOS. Additionally, a department at the Chemnitz University of Technology has developed preliminary support for the TMS320C6x series in the GNU Compiler Collection.[15]

In November 2007 TI released part of its toolchain as freeware for non-commercial users, offering the bare compiler, assembler, optimizer and linker under a proprietary license.[16] [17] However, neither the IDE nor a debugger were included, so for debugging and JTAG access to the DSPs, users still need to purchase the complete toolchain.

In 2010 Texas Instruments contracted CodeSourcery (the assignment later transferred to Mentor Graphics as part of their acquisition) to provide deep integration and support for the C6x series in GCC, as part of their effort to port the Linux kernel to C6x. This culminated in C6x being a supported architecture in GCC release 4.7 on March 22, 2012.[18]

See also

References

  1. Web site: The TMS320C30 Floating-Point Digital Signal Processor . 2023-11-04 . ti.com . 14 .
  2. Web site: TMS320C25 . . 10 December 2019.
  3. Web site: TMS320 SECOND GENERATION DIGITAL SIGNAL PROCESSORS . Texas Instruments . 7 December 2023.
  4. Web site: TMS320C40 . Texas Instruments . 10 December 2019.
  5. Web site: TMS320C4x User's Guide . 2023-12-23 . 171(7-9).
  6. Guttag . Karl . (USA) . Texas Instruments Inc. . Joseph . Picone . TMS320C8x family architecture and future roadmap . Digital Signal Processing Technology . 2750 . 2–11 . June 7, 1996 . 10.1117/12.241977 . January 7, 2017. 1996SPIE.2750....2G . 60536785 .
  7. Web site: TMS320C54x DSP Reference Set - Volume 1: CPU and Peripherals . 2024-08-06 . www.ti.com.
  8. this Web site: LinuxDevices article. https://archive.today/20130128094646/http://www.linuxfordevices.com/c/a/News/TI-adds-ARM9-Linux-to-sound-chip/. 2013-01-28. dead. includes more informationabout this platform
  9. this Web site: IC Database . 2009-09-22 . dead . https://web.archive.org/web/20091228101515/http://members.cox.net/alexhardware/IC_database1.htm . 2009-12-28 . site includes more information
  10. Book: Heuer , Gert . Digitaler Signalprozessor U320C20. Digital signal processor U320C20. German. Verlag Technik. Berlin. 1991. 978-3341009987.
  11. Web site: DSP-процессоры. DSP processors. OAO "NIIET". Voronezh. Russian. https://web.archive.org/web/20180626081353/http://niiet.ru/goods/chips/cos. 26 June 2018. niiet.ru. 2 December 2019.
  12. Web site: 1967ВЦ1Т (аналог TMS320C546). 1967VC1T (corresponding to TMS320C546). PKK Milandr. Moscow. Russian. 20 May 2009. 9 January 2017.
  13. Web site: Микропроцессоры и микроконтроллеры. Microprocessors and microcontrollers. MVC. Nizhny Novgorod. Russian. https://web.archive.org/web/20170510071936/http://mvc-nn.ru/%d0%bf%d1%80%d0%be%d0%b4%d1%83%d0%ba%d1%86%d0%b8%d1%8f/%d0%bc%d0%b8%d0%ba%d1%80%d0%be%d0%bf%d1%80%d0%be%d1%86%d0%b5%d1%81%d1%81%d0%be%d1%80%d1%8b-%d0%b8-%d0%bc%d0%b8%d0%ba%d1%80%d0%be%d0%ba%d0%be%d0%bd%d1%82%d1%80%d0%be%d0%bb%d0%bb%d0%b5%d1%80%d1%8b/. 10 May 2017. 2014. 18 April 2018.
  14. Web site: Двухъядерный микроконтроллер компании "Миландр" для высоконадёжных применений. Dual-core microcontroller from Company "Milandr" for high-reliability applications. PKK Milandr. Moscow. Russian. https://web.archive.org/web/20160427150319/http://www.milandr.ru/uploads/doc_img/other/publications/2011.07_(N_07)_Dvuhyadernuy%20mikrokontroller%20kompanii%20Milandr_EK.pdf. 27 April 2016. 18 April 2018.
  15. Jan Parthey and Robert Baumgartl, Porting GCC to the TMS320-C6000 DSP Architecture, Appeared in the Proceedings of GSPx’04, Santa Clara, September 2004, https://web.archive.org/web/20070610084245/http://rtg.informatik.tu-chemnitz.de/docs/pubs/gspx04.pdf
  16. Web site: TI frees its DSP toolchain. https://archive.today/20130127211547/http://www.linuxfordevices.com/c/a/News/TI-frees-its-DSP-toolchain-for-open-source-apps/. 2013-01-27. dead.
  17. http://open.neurostechnology.com/node/1020 Free DSP Compiler Available
  18. https://gcc.gnu.org/gcc-4.7/changes.html GCC 4.7 Release Series – Changes, New Features, and Fixes

External links