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Static random-access memory

January 01, 1970

Not to be confused with synchronous dynamic random-access memory (SDRAM).

Static random-access memory (static RAM or SRAM) is a type of random-access memory (RAM) that uses latching circuitry (flip-flop) to store each bit. SRAM is volatile memory; data is lost when power is removed.

A static RAM chip from a Nintendo Entertainment System clone (2K × 8 bits)

The term static differentiates SRAM from DRAM (dynamic random-access memory):

  • SRAM will hold its data permanently in the presence of power, while data in DRAM decays in seconds and thus must be periodically refreshed.
  • SRAM is faster than DRAM but it is more expensive in terms of silicon area and cost.
  • SRAM is typically used for the cache and internal registers of a CPU while DRAM is used for a computer's main memory.

History edit

Semiconductor bipolar SRAM was invented in 1963 by Robert Norman at Fairchild Semiconductor.[1] The metal–oxide–semiconductor SRAM (MOS-SRAM) was invented in 1964 by John Schmidt at Fairchild Semiconductor. It was a 64-bit MOS p-channel SRAM.[2][3]

SRAM was the main driver behind any new CMOS-based technology fabrication process since 1959 when CMOS was invented.[4]

In 1964, Arnold Farber and Eugene Schlig, working for IBM, created a hard-wired memory cell, using a transistor gate and tunnel diode latch. They replaced the latch with two transistors and two resistors, a configuration that became known as the Farber-Schlig cell. That year they submitted an invention disclosure, but it was initially rejected.[5][6] In 1965, Benjamin Agusta and his team at IBM created a 16-bit silicon memory chip based on the Farber-Schlig cell, with 80 transistors, 64 resistors, and 4 diodes.

In April 1969, Intel Inc. introduced its first product, Intel 3101, a SRAM memory chip intended to replace bulky magnetic-core memory modules; Its capacity was 64 bits (In the first versions, only 63 bits were usable due to a bug)[7] and was based on bipolar junction transistors[8] it was designed by using rubylith.[9]

Characteristics edit

Though it can be characterized as volatile memory, SRAM exhibits data remanence.[10]

SRAM offers a simple data access model and does not require a refresh circuit. Performance and reliability are good and power consumption is low when idle.[11]

Since SRAM requires more transistors per bit to implement, it is less dense and more expensive than DRAM and also has a higher power consumption during read or write access. The power consumption of SRAM varies widely depending on how frequently it is accessed.[11]

Applications edit

 
SRAM cells on the die of a STM32F103VGT6 microcontroller as seen by a scanning electron microscope. Manufactured by STMicroelectronics using a 180-nanometre process. Topology of the cells is clearly visible.
 
Comparison image of 180 nanometre SRAM cells on a STM32F103VGT6 microcontroller as seen by an optical microscope

Embedded use edit

Many categories of industrial and scientific subsystems, automotive electronics, and similar embedded systems, contain SRAM which, in this context, may be referred to as ESRAM.[12] Some amount (kilobytes or less) is also embedded in practically all modern appliances, toys, etc. that implement an electronic user interface.

SRAM in its dual-ported form is sometimes used for real-time digital signal processing circuits.[13]

In computers edit

SRAM is also used in personal computers, workstations, routers and peripheral equipment: CPU register files, internal CPU caches, internal GPU caches and external burst mode SRAM caches, hard disk buffers, router buffers, etc. LCD screens and printers also normally employ SRAM to hold the image displayed (or to be printed). LCDs can have SRAM in their LCD controllers. SRAM was used for the main memory of many early personal computers such as the ZX80, TRS-80 Model 100, and VIC-20.

Some early memory cards in the late 1980s to early 1990s used SRAM as a storage medium, which required a lithium battery to keep the contents of the SRAM.[14][15]

Integrated on chip edit

SRAM may be integrated on chip for:

Hobbyists edit

Hobbyists, specifically home-built processor enthusiasts,[16] often prefer SRAM due to the ease of interfacing. It is much easier to work with than DRAM as there are no refresh cycles and the address and data buses are often directly accessible.[citation needed] In addition to buses and power connections, SRAM usually requires only three controls: Chip Enable (CE), Write Enable (WE) and Output Enable (OE). In synchronous SRAM, Clock (CLK) is also included.[17]

Types of SRAM edit

Non-volatile SRAM edit

Non-volatile SRAM (nvSRAM) has standard SRAM functionality, but they save the data when the power supply is lost, ensuring preservation of critical information. nvSRAMs are used in a wide range of situations – networking, aerospace, and medical, among many others[18] – where the preservation of data is critical and where batteries are impractical.

Pseudostatic RAM edit

Pseudostatic RAM (PSRAM) is DRAM combined with a self-refresh circuit.[19] It appears externally as slower SRAM, albeit with a density and cost advantage over true SRAM, and without the access complexity of DRAM.

By transistor type edit

By numeral system edit

By function edit

  • Asynchronous – independent of clock frequency; data in and data out are controlled by address transition. Examples include the ubiquitous 28-pin 8K × 8 and 32K × 8 chips (often but not always named something along the lines of 6264 and 62C256 respectively), as well as similar products up to 16 Mbit per chip.
  • Synchronous – all timings are initiated by the clock edges. Address, data in and other control signals are associated with the clock signals.

In the 1990s, asynchronous SRAM used to be employed for fast access time. Asynchronous SRAM was used as main memory for small cache-less embedded processors used in everything from industrial electronics and measurement systems to hard disks and networking equipment, among many other applications. Nowadays, synchronous SRAM (e.g. DDR SRAM) is rather employed similarly to synchronous DRAM – DDR SDRAM memory is rather used than asynchronous DRAM. Synchronous memory interface is much faster as access time can be significantly reduced by employing pipeline architecture. Furthermore, as DRAM is much cheaper than SRAM, SRAM is often replaced by DRAM, especially in the case when a large volume of data is required. SRAM memory is, however, much faster for random (not block / burst) access. Therefore, SRAM memory is mainly used for CPU cache, small on-chip memory, FIFOs or other small buffers.

By feature edit

  • Zero bus turnaround (ZBT) – the turnaround is the number of clock cycles it takes to change access to SRAM from write to read and vice versa. The turnaround for ZBT SRAMs or the latency between read and write cycle is zero.
  • syncBurst (syncBurst SRAM or synchronous-burst SRAM) – features synchronous burst write access to SRAM to increase write operation to SRAM.
  • DDR SRAM – synchronous, single read/write port, double data rate I/O.
  • Quad Data Rate SRAM – synchronous, separate read and write ports, quadruple data rate I/O.

Design edit

 
A six-transistor CMOS SRAM cell. WL: word line. BL: bit line.

A typical SRAM cell is made up of six MOSFETs, and is often called a 6T SRAM cell. Each bit in the cell is stored on four transistors (M1, M2, M3, M4) that form two cross-coupled inverters. This storage cell has two stable states which are used to denote 0 and 1. Two additional access transistors serve to control the access to a storage cell during read and write operations. 6T SRAM is the most common kind of SRAM.[20] In addition to 6T SRAM, other kinds of SRAM use 4, 5, 7,[21] 8, 9,[20] 10[22] (4T, 5T, 7T 8T, 9T, 10T SRAM), or more transistors per bit.[23][24][25] Four-transistor SRAM is quite common in stand-alone SRAM devices (as opposed to SRAM used for CPU caches), implemented in special processes with an extra layer of polysilicon, allowing for very high-resistance pull-up resistors.[26] The principal drawback of using 4T SRAM is increased static power due to the constant current flow through one of the pull-down transistors (M1 or M2).

 
Four-transistor SRAM provides advantages in density at the cost of manufacturing complexity. The resistors must have small dimensions and large values.

This is sometimes used to implement more than one (read and/or write) port, which may be useful in certain types of video memory and register files implemented with multi-ported SRAM circuitry.

Generally, the fewer transistors needed per cell, the smaller each cell can be. Since the cost of processing a silicon wafer is relatively fixed, using smaller cells and so packing more bits on one wafer reduces the cost per bit of memory.

Memory cells that use fewer than four transistors are possible; however, such 3T[27][28] or 1T cells are DRAM, not SRAM (even the so-called 1T-SRAM).

Access to the cell is enabled by the word line (WL in figure) which controls the two access transistors M5 and M6 which, in turn, control whether the cell should be connected to the bit lines: BL and BL. They are used to transfer data for both read and write operations. Although it is not strictly necessary to have two bit lines, both the signal and its inverse are typically provided in order to improve noise margins and speed.

During read accesses, the bit lines are actively driven high and low by the inverters in the SRAM cell. This improves SRAM bandwidth compared to DRAMs – in a DRAM, the bit line is connected to storage capacitors and charge sharing causes the bit line to swing upwards or downwards. The symmetric structure of SRAMs also allows for differential signaling, which makes small voltage swings more easily detectable. Another difference with DRAM that contributes to making SRAM faster is that commercial chips accept all address bits at a time. By comparison, commodity DRAMs have the address multiplexed in two halves, i.e. higher bits followed by lower bits, over the same package pins in order to keep their size and cost down.

The size of an SRAM with m address lines and n data lines is 2m words, or 2m × n bits. The most common word size is 8 bits, meaning that a single byte can be read or written to each of 2m different words within the SRAM chip. Several common SRAM chips have 11 address lines (thus a capacity of 211 = 2,048 = 2k words) and an 8-bit word, so they are referred to as "2k × 8 SRAM".

The dimensions of an SRAM cell on an IC is determined by the minimum feature size of the process used to make the IC.

SRAM operation edit

An SRAM cell has three states:

  • Standby: The circuit is idle.
  • Reading: The data has been requested.
  • Writing: Updating the contents.

SRAM operating in read and write modes should have "readability" and "write stability", respectively. The three different states work as follows:

Standby edit

If the word line is not asserted, the access transistors M5 and M6 disconnect the cell from the bit lines. The two cross-coupled inverters formed by M1 – M4 will continue to reinforce each other as long as they are connected to the supply.

Reading edit

In theory, reading only requires asserting the word line WL and reading the SRAM cell state by a single access transistor and bit line, e.g. M6, BL. However, bit lines are relatively long and have large parasitic capacitance. To speed up reading, a more complex process is used in practice: The read cycle is started by precharging both bit lines BL and BL, to high (logic 1) voltage. Then asserting the word line WL enables both the access transistors M5 and M6, which causes one bit line BL voltage to slightly drop. Then the BL and BL lines will have a small voltage difference between them. A sense amplifier will sense which line has the higher voltage and thus determine whether there was 1 or 0 stored. The higher the sensitivity of the sense amplifier, the faster the read operation. As the NMOS is more powerful, the pull-down is easier. Therefore, bit lines are traditionally precharged to high voltage. Many researchers are also trying to precharge at a slightly low voltage to reduce the power consumption.[29][30]

Writing edit

The write cycle begins by applying the value to be written to the bit lines. To write a 0, a 0 is applied to the bit lines, such as setting BL to 1 and BL to 0. This is similar to applying a reset pulse to an SR-latch, which causes the flip flop to change state. A 1 is written by inverting the values of the bit lines. WL is then asserted and the value that is to be stored is latched in. This works because the bit line input-drivers are designed to be much stronger than the relatively weak transistors in the cell itself so they can easily override the previous state of the cross-coupled inverters. In practice, access NMOS transistors M5 and M6 have to be stronger than either bottom NMOS (M1, M3) or top PMOS (M2, M4) transistors. This is easily obtained as PMOS transistors are much weaker than NMOS when same sized. Consequently, when one transistor pair (e.g. M3 and M4) is only slightly overridden by the write process, the opposite transistors pair (M1 and M2) gate voltage is also changed. This means that the M1 and M2 transistors can be easier overridden, and so on. Thus, cross-coupled inverters magnify the writing process.

Bus behavior edit

RAM with an access time of 70 ns will output valid data within 70 ns from the time that the address lines are valid. Some SRAM cells have a "page mode", where words of a page (256, 512, or 1024 words) can be read sequentially with a significantly shorter access time (typically approximately 30 ns). The page is selected by setting the upper address lines and then words are sequentially read by stepping through the lower address lines.

Production challenges edit

With the introduction of the FinFET transistor implementation of SRAM cells, they started to suffer from increasing inefficiencies in cell sizes. Over the last 30 years (from 1987 to 2017) with a steadily decreasing transistor size (node size) the footprint-shrinking of the SRAM cell topology itself slowed down, making it harder to pack the cells more densely.[4]

Besides issues with size a significant challenge of modern SRAM cells is a static current leakage. The current, that flows from positive supply (Vdd), through the cell, and to the ground, increases exponentially when the cell's temperature rises. The cell power drain occurs in both active and idle states, thus wasting useful energy without any useful work done. Even though in the last 20 years the issue was partially addressed by the Data Retention Voltage technique (DRV) with reduction rates ranging from 5 to 10, the decrease in node size caused reduction rates to fall to about 2.[4]

With these two issues it became more challenging to develop energy-efficient and dense SRAM memories, prompting semiconductor industry to look for alternatives such as STT-MRAM and F-RAM.[4][31]

Research edit

In 2019 a French institute reported on a research of an IoT-purposed 28nm fabricated IC.[32] It was based on fully depleted silicon on insulator-transistors (FD-SOI), had two-ported SRAM memory rail for synchronous/asynchronous accesses, and selective virtual ground (SVGND). The study claimed reaching an ultra-low SVGND current in a "sleep" and read modes by finely tuning its voltage.[32]

See also edit

 
Wikimedia Commons has media related to SRAM and CMOS_RAM.

References edit

  1. ^ "1966: Semiconductor RAMs Serve High-speed Storage Needs". Computer History Museum. Retrieved 19 June 2019.
  2. ^ "1970: MOS dynamic RAM competes with magnetic core memory on price". Computer History Museum.
  3. ^ "Memory lectures" (PDF).
  4. ^ a b c d Walker, Andrew (December 17, 2018). "The Trouble with SRAM". EE Times.
  5. ^ US 3354440A, Arnold S. Farber & Eugene S. Schlig, "Nondestructive memory array", issued 1967-11-21, assigned to IBM [dead link]
  6. ^ Emerson W. Pugh; Lyle R. Johnson; John H. Palmer (1991). IBM's 360 and Early 370 Systems. MIT Press. p. 462. ISBN 9780262161237.
  7. ^ Volk, Andrew M.; Stoll, Peter A.; Metrovich, Paul (First Quarter 2001). "Recollections of Early Chip Development at Intel" (PDF). Intel Technology Journal. 5 (1): 11 – via Intel.
  8. ^ . Intel Newsroom. 2018-05-14. Archived from the original on 2023-02-01. Retrieved 2023-02-01.
  9. ^ Intel 64 bit static RAM rubylith : 6, c. 1970, retrieved 2023-01-28
  10. ^ Sergei Skorobogatov (June 2002). "Low temperature data remanence in static RAM". University of Cambridge, Computer Laboratory. doi:10.48456/tr-536. Retrieved 2008-02-27.
  11. ^ a b Null, Linda; Lobur, Julia (2006). The Essentials of Computer Organization and Architecture. Jones and Bartlett Publishers. p. 282. ISBN 978-0763737696. Retrieved 2021-09-14.
  12. ^ Fahad Arif (Apr 5, 2014). "Microsoft Says Xbox One's ESRAM is a "Huge Win" – Explains How it Allows Reaching 1080p/60 FPS". Retrieved 2020-03-24.
  13. ^ Shared Memory Interface with the TMS320C54x DSP (PDF), retrieved 2019-05-04
  14. ^ Stam, Nick (December 21, 1993). "PCMCIA's System Architecture". PC Mag. Ziff Davis, Inc. – via Google Books.
  15. ^ Matzkin, Jonathan (December 26, 1989). "$399 Atari Portfolio Takes on Hand-held Poqet PC". PC Mag. Ziff Davis, Inc. – via Google Books.
  16. ^ "Homemade CPU – from scratch : Svarichevsky Mikhail". 3.14.by.
  17. ^ "Embedded Systems Course- module 15: SRAM memory interface to microcontroller in embedded systems". Retrieved 2024-04-12.
  18. ^ Computer organization (4th ed.). [S.l.]: McGraw-Hill. 1996-07-01. ISBN 978-0-07-114323-3.
  19. ^ "3.0V Core Async/Page PSRAM Memory" (PDF). Micron. Retrieved 2019-05-04.
  20. ^ a b Rathi, Neetu; Kumar, Anil; Gupta, Neeraj; Singh, Sanjay Kumar (2023). "A Review of Low-Power Static Random Access Memory (SRAM) Designs". 2023 IEEE Devices for Integrated Circuit (DevIC). pp. 455–459. doi:10.1109/DevIC57758.2023.10134887. ISBN 979-8-3503-4726-5. S2CID 258984439.
  21. ^ Chen, Wai-Kai (October 3, 2018). The VLSI Handbook. CRC Press. ISBN 978-1-4200-0596-7 – via Google Books.
  22. ^ Kulkarni, Jaydeep P.; Kim, Keejong; Roy, Kaushik (2007). "A 160 mV Robust Schmitt Trigger Based Subthreshold SRAM". IEEE Journal of Solid-State Circuits. 42 (10): 2303. Bibcode:2007IJSSC..42.2303K. doi:10.1109/JSSC.2007.897148. S2CID 699469.
  23. ^ "0.45-V operating Vt-variation tolerant 9T/18T dual-port SRAM". March 2011. pp. 1–4. doi:10.1109/ISQED.2011.5770728. S2CID 6397769.
  24. ^ United States Patent 6975532: Quasi-static random access memory
  25. ^ . Archived from the original on 2008-12-05.
  26. ^ Preston, Ronald P. (2001). (PDF). The Design of High Performance Microprocessor Circuits. IEEE Press. p. 290. Archived from the original (PDF) on 2013-05-09. Retrieved 2013-02-01.
  27. ^ United States Patent 6975531: 6F2 3-transistor DRAM gain cell
  28. ^ 3T-iRAM(r) Technology
  29. ^ Kabir, Hussain Mohammed Dipu; Chan, Mansun (January 2, 2015). "SRAM precharge system for reducing write power". HKIE Transactions. 22 (1): 1–8. doi:10.1080/1023697X.2014.970761. S2CID 108574841 – via CrossRef.
  30. ^ "CiteSeerX". CiteSeerX. CiteSeerX 10.1.1.119.3735.
  31. ^ Walker, Andrew (February 6, 2019). "The Race is On". EE Times.
  32. ^ a b Reda, Boumchedda (May 20, 2019). "Ultra-low voltage and energy efficient SRAM design with new technologies for IoT applications". Grenoble Alpes University.

January 01, 1970
static, random, access, memory, confused, with, synchronous, dynamic, random, access, memory, sdram, static, sram, type, random, access, memory, that, uses, latching, circuitry, flip, flop, store, each, sram, volatile, memory, data, lost, when, power, removed,. Not to be confused with synchronous dynamic random access memory SDRAM Static random access memory static RAM or SRAM is a type of random access memory RAM that uses latching circuitry flip flop to store each bit SRAM is volatile memory data is lost when power is removed A static RAM chip from a Nintendo Entertainment System clone 2K 8 bits The term static differentiates SRAM from DRAM dynamic random access memory SRAM will hold its data permanently in the presence of power while data in DRAM decays in seconds and thus must be periodically refreshed SRAM is faster than DRAM but it is more expensive in terms of silicon area and cost SRAM is typically used for the cache and internal registers of a CPU while DRAM is used for a computer s main memory Contents 1 History 2 Characteristics 3 Applications 3 1 Embedded use 3 2 In computers 3 3 Integrated on chip 3 4 Hobbyists 4 Types of SRAM 4 1 Non volatile SRAM 4 2 Pseudostatic RAM 4 3 By transistor type 4 4 By numeral system 4 5 By function 4 6 By feature 5 Design 6 SRAM operation 6 1 Standby 6 2 Reading 6 3 Writing 6 4 Bus behavior 7 Production challenges 7 1 Research 8 See also 9 ReferencesHistory editSemiconductor bipolar SRAM was invented in 1963 by Robert Norman at Fairchild Semiconductor 1 The metal oxide semiconductor SRAM MOS SRAM was invented in 1964 by John Schmidt at Fairchild Semiconductor It was a 64 bit MOS p channel SRAM 2 3 SRAM was the main driver behind any new CMOS based technology fabrication process since 1959 when CMOS was invented 4 In 1964 Arnold Farber and Eugene Schlig working for IBM created a hard wired memory cell using a transistor gate and tunnel diode latch They replaced the latch with two transistors and two resistors a configuration that became known as the Farber Schlig cell That year they submitted an invention disclosure but it was initially rejected 5 6 In 1965 Benjamin Agusta and his team at IBM created a 16 bit silicon memory chip based on the Farber Schlig cell with 80 transistors 64 resistors and 4 diodes In April 1969 Intel Inc introduced its first product Intel 3101 a SRAM memory chip intended to replace bulky magnetic core memory modules Its capacity was 64 bits In the first versions only 63 bits were usable due to a bug 7 and was based on bipolar junction transistors 8 it was designed by using rubylith 9 Characteristics editThough it can be characterized as volatile memory SRAM exhibits data remanence 10 SRAM offers a simple data access model and does not require a refresh circuit Performance and reliability are good and power consumption is low when idle 11 Since SRAM requires more transistors per bit to implement it is less dense and more expensive than DRAM and also has a higher power consumption during read or write access The power consumption of SRAM varies widely depending on how frequently it is accessed 11 Applications edit nbsp SRAM cells on the die of a STM32F103VGT6 microcontroller as seen by a scanning electron microscope Manufactured by STMicroelectronics using a 180 nanometre process Topology of the cells is clearly visible nbsp Comparison image of 180 nanometre SRAM cells on a STM32F103VGT6 microcontroller as seen by an optical microscope Embedded use edit Many categories of industrial and scientific subsystems automotive electronics and similar embedded systems contain SRAM which in this context may be referred to as ESRAM 12 Some amount kilobytes or less is also embedded in practically all modern appliances toys etc that implement an electronic user interface SRAM in its dual ported form is sometimes used for real time digital signal processing circuits 13 In computers edit SRAM is also used in personal computers workstations routers and peripheral equipment CPU register files internal CPU caches internal GPU caches and external burst mode SRAM caches hard disk buffers router buffers etc LCD screens and printers also normally employ SRAM to hold the image displayed or to be printed LCDs can have SRAM in their LCD controllers SRAM was used for the main memory of many early personal computers such as the ZX80 TRS 80 Model 100 and VIC 20 Some early memory cards in the late 1980s to early 1990s used SRAM as a storage medium which required a lithium battery to keep the contents of the SRAM 14 15 Integrated on chip edit SRAM may be integrated on chip for the RAM in microcontrollers usually from around 32 bytes to a megabyte the on chip caches in more powerful CPUs such as the x86 family and many others from 8 KB up to many megabytes the registers and parts of the state machines used in some microprocessors see register file scratchpad memory application specific integrated circuits ASICs usually in the order of kilobytes and in field programmable gate arrays FPGAs and complex programmable logic devices CPLDs Hobbyists edit Hobbyists specifically home built processor enthusiasts 16 often prefer SRAM due to the ease of interfacing It is much easier to work with than DRAM as there are no refresh cycles and the address and data buses are often directly accessible citation needed In addition to buses and power connections SRAM usually requires only three controls Chip Enable CE Write Enable WE and Output Enable OE In synchronous SRAM Clock CLK is also included 17 Types of SRAM editNon volatile SRAM edit Non volatile SRAM nvSRAM has standard SRAM functionality but they save the data when the power supply is lost ensuring preservation of critical information nvSRAMs are used in a wide range of situations networking aerospace and medical among many others 18 where the preservation of data is critical and where batteries are impractical Pseudostatic RAM edit Pseudostatic RAM PSRAM is DRAM combined with a self refresh circuit 19 It appears externally as slower SRAM albeit with a density and cost advantage over true SRAM and without the access complexity of DRAM By transistor type edit Bipolar junction transistor used in TTL and ECL very fast but with high power consumption MOSFET used in CMOS low power By numeral system edit Binary Ternary By function edit Asynchronous independent of clock frequency data in and data out are controlled by address transition Examples include the ubiquitous 28 pin 8K 8 and 32K 8 chips often but not always named something along the lines of 6264 and 62C256 respectively as well as similar products up to 16 Mbit per chip Synchronous all timings are initiated by the clock edges Address data in and other control signals are associated with the clock signals In the 1990s asynchronous SRAM used to be employed for fast access time Asynchronous SRAM was used as main memory for small cache less embedded processors used in everything from industrial electronics and measurement systems to hard disks and networking equipment among many other applications Nowadays synchronous SRAM e g DDR SRAM is rather employed similarly to synchronous DRAM DDR SDRAM memory is rather used than asynchronous DRAM Synchronous memory interface is much faster as access time can be significantly reduced by employing pipeline architecture Furthermore as DRAM is much cheaper than SRAM SRAM is often replaced by DRAM especially in the case when a large volume of data is required SRAM memory is however much faster for random not block burst access Therefore SRAM memory is mainly used for CPU cache small on chip memory FIFOs or other small buffers By feature edit Zero bus turnaround ZBT the turnaround is the number of clock cycles it takes to change access to SRAM from write to read and vice versa The turnaround for ZBT SRAMs or the latency between read and write cycle is zero syncBurst syncBurst SRAM or synchronous burst SRAM features synchronous burst write access to SRAM to increase write operation to SRAM DDR SRAM synchronous single read write port double data rate I O Quad Data Rate SRAM synchronous separate read and write ports quadruple data rate I O Design edit nbsp A six transistor CMOS SRAM cell WL word line BL bit line A typical SRAM cell is made up of six MOSFETs and is often called a 6T SRAM cell Each bit in the cell is stored on four transistors M1 M2 M3 M4 that form two cross coupled inverters This storage cell has two stable states which are used to denote 0 and 1 Two additional access transistors serve to control the access to a storage cell during read and write operations 6T SRAM is the most common kind of SRAM 20 In addition to 6T SRAM other kinds of SRAM use 4 5 7 21 8 9 20 10 22 4T 5T 7T 8T 9T 10T SRAM or more transistors per bit 23 24 25 Four transistor SRAM is quite common in stand alone SRAM devices as opposed to SRAM used for CPU caches implemented in special processes with an extra layer of polysilicon allowing for very high resistance pull up resistors 26 The principal drawback of using 4T SRAM is increased static power due to the constant current flow through one of the pull down transistors M1 or M2 nbsp Four transistor SRAM provides advantages in density at the cost of manufacturing complexity The resistors must have small dimensions and large values This is sometimes used to implement more than one read and or write port which may be useful in certain types of video memory and register files implemented with multi ported SRAM circuitry Generally the fewer transistors needed per cell the smaller each cell can be Since the cost of processing a silicon wafer is relatively fixed using smaller cells and so packing more bits on one wafer reduces the cost per bit of memory Memory cells that use fewer than four transistors are possible however such 3T 27 28 or 1T cells are DRAM not SRAM even the so called 1T SRAM Access to the cell is enabled by the word line WL in figure which controls the two access transistors M5 and M6 which in turn control whether the cell should be connected to the bit lines BL and BL They are used to transfer data for both read and write operations Although it is not strictly necessary to have two bit lines both the signal and its inverse are typically provided in order to improve noise margins and speed During read accesses the bit lines are actively driven high and low by the inverters in the SRAM cell This improves SRAM bandwidth compared to DRAMs in a DRAM the bit line is connected to storage capacitors and charge sharing causes the bit line to swing upwards or downwards The symmetric structure of SRAMs also allows for differential signaling which makes small voltage swings more easily detectable Another difference with DRAM that contributes to making SRAM faster is that commercial chips accept all address bits at a time By comparison commodity DRAMs have the address multiplexed in two halves i e higher bits followed by lower bits over the same package pins in order to keep their size and cost down The size of an SRAM with m address lines and n data lines is 2m words or 2m n bits The most common word size is 8 bits meaning that a single byte can be read or written to each of 2m different words within the SRAM chip Several common SRAM chips have 11 address lines thus a capacity of 211 2 048 2k words and an 8 bit word so they are referred to as 2k 8 SRAM The dimensions of an SRAM cell on an IC is determined by the minimum feature size of the process used to make the IC SRAM operation editThis section is written like a manual or guide Please help rewrite this section and remove advice or instruction January 2023 An SRAM cell has three states Standby The circuit is idle Reading The data has been requested Writing Updating the contents SRAM operating in read and write modes should have readability and write stability respectively The three different states work as follows Standby edit If the word line is not asserted the access transistors M5 and M6 disconnect the cell from the bit lines The two cross coupled inverters formed by M1 M4 will continue to reinforce each other as long as they are connected to the supply Reading edit In theory reading only requires asserting the word line WL and reading the SRAM cell state by a single access transistor and bit line e g M6 BL However bit lines are relatively long and have large parasitic capacitance To speed up reading a more complex process is used in practice The read cycle is started by precharging both bit lines BL and BL to high logic 1 voltage Then asserting the word line WL enables both the access transistors M5 and M6 which causes one bit line BL voltage to slightly drop Then the BL and BL lines will have a small voltage difference between them A sense amplifier will sense which line has the higher voltage and thus determine whether there was 1 or 0 stored The higher the sensitivity of the sense amplifier the faster the read operation As the NMOS is more powerful the pull down is easier Therefore bit lines are traditionally precharged to high voltage Many researchers are also trying to precharge at a slightly low voltage to reduce the power consumption 29 30 Writing edit The write cycle begins by applying the value to be written to the bit lines To write a 0 a 0 is applied to the bit lines such as setting BL to 1 and BL to 0 This is similar to applying a reset pulse to an SR latch which causes the flip flop to change state A 1 is written by inverting the values of the bit lines WL is then asserted and the value that is to be stored is latched in This works because the bit line input drivers are designed to be much stronger than the relatively weak transistors in the cell itself so they can easily override the previous state of the cross coupled inverters In practice access NMOS transistors M5 and M6 have to be stronger than either bottom NMOS M1 M3 or top PMOS M2 M4 transistors This is easily obtained as PMOS transistors are much weaker than NMOS when same sized Consequently when one transistor pair e g M3 and M4 is only slightly overridden by the write process the opposite transistors pair M1 and M2 gate voltage is also changed This means that the M1 and M2 transistors can be easier overridden and so on Thus cross coupled inverters magnify the writing process Bus behavior edit RAM with an access time of 70 ns will output valid data within 70 ns from the time that the address lines are valid Some SRAM cells have a page mode where words of a page 256 512 or 1024 words can be read sequentially with a significantly shorter access time typically approximately 30 ns The page is selected by setting the upper address lines and then words are sequentially read by stepping through the lower address lines Production challenges editWith the introduction of the FinFET transistor implementation of SRAM cells they started to suffer from increasing inefficiencies in cell sizes Over the last 30 years from 1987 to 2017 with a steadily decreasing transistor size node size the footprint shrinking of the SRAM cell topology itself slowed down making it harder to pack the cells more densely 4 Besides issues with size a significant challenge of modern SRAM cells is a static current leakage The current that flows from positive supply Vdd through the cell and to the ground increases exponentially when the cell s temperature rises The cell power drain occurs in both active and idle states thus wasting useful energy without any useful work done Even though in the last 20 years the issue was partially addressed by the Data Retention Voltage technique DRV with reduction rates ranging from 5 to 10 the decrease in node size caused reduction rates to fall to about 2 4 With these two issues it became more challenging to develop energy efficient and dense SRAM memories prompting semiconductor industry to look for alternatives such as STT MRAM and F RAM 4 31 Research edit In 2019 a French institute reported on a research of an IoT purposed 28nm fabricated IC 32 It was based on fully depleted silicon on insulator transistors FD SOI had two ported SRAM memory rail for synchronous asynchronous accesses and selective virtual ground SVGND The study claimed reaching an ultra low SVGND current in a sleep and read modes by finely tuning its voltage 32 See also edit nbsp Wikimedia Commons has media related to wbr SRAM and wbr CMOS RAM Flash memory Miniature Card a discontinued SRAM memory card standard In memory processingReferences edit 1966 Semiconductor RAMs Serve High speed Storage Needs Computer History Museum Retrieved 19 June 2019 1970 MOS dynamic RAM competes with magnetic core memory on price Computer History Museum Memory lectures PDF a b c d Walker Andrew December 17 2018 The Trouble with SRAM EE Times US 3354440A Arnold S Farber amp Eugene S Schlig Nondestructive memory array issued 1967 11 21 assigned to IBM dead link Emerson W Pugh Lyle R Johnson John H Palmer 1991 IBM s 360 and Early 370 Systems MIT Press p 462 ISBN 9780262161237 Volk Andrew M Stoll Peter A Metrovich Paul First Quarter 2001 Recollections of Early Chip Development at Intel PDF Intel Technology Journal 5 1 11 via Intel Intel at 50 Intel s First Product the 3101 Intel Newsroom 2018 05 14 Archived from the original on 2023 02 01 Retrieved 2023 02 01 Intel 64 bit static RAM rubylith 6 c 1970 retrieved 2023 01 28 Sergei Skorobogatov June 2002 Low temperature data remanence in static RAM University of Cambridge Computer Laboratory doi 10 48456 tr 536 Retrieved 2008 02 27 a b Null Linda Lobur Julia 2006 The Essentials of Computer Organization and Architecture Jones and Bartlett Publishers p 282 ISBN 978 0763737696 Retrieved 2021 09 14 Fahad Arif Apr 5 2014 Microsoft Says Xbox One s ESRAM is a Huge Win Explains How it Allows Reaching 1080p 60 FPS Retrieved 2020 03 24 Shared Memory Interface with the TMS320C54x DSP PDF retrieved 2019 05 04 Stam Nick December 21 1993 PCMCIA s System Architecture PC Mag Ziff Davis Inc via Google Books Matzkin Jonathan December 26 1989 399 Atari Portfolio Takes on Hand held Poqet PC PC Mag Ziff Davis Inc via Google Books Homemade CPU from scratch Svarichevsky Mikhail 3 14 by Embedded Systems Course module 15 SRAM memory interface to microcontroller in embedded systems Retrieved 2024 04 12 Computer organization 4th ed S l McGraw Hill 1996 07 01 ISBN 978 0 07 114323 3 3 0V Core Async Page PSRAM Memory PDF Micron Retrieved 2019 05 04 a b Rathi Neetu Kumar Anil Gupta Neeraj Singh Sanjay Kumar 2023 A Review of Low Power Static Random Access Memory SRAM Designs 2023 IEEE Devices for Integrated Circuit DevIC pp 455 459 doi 10 1109 DevIC57758 2023 10134887 ISBN 979 8 3503 4726 5 S2CID 258984439 Chen Wai Kai October 3 2018 The VLSI Handbook CRC Press ISBN 978 1 4200 0596 7 via Google Books Kulkarni Jaydeep P Kim Keejong Roy Kaushik 2007 A 160 mV Robust Schmitt Trigger Based Subthreshold SRAM IEEE Journal of Solid State Circuits 42 10 2303 Bibcode 2007IJSSC 42 2303K doi 10 1109 JSSC 2007 897148 S2CID 699469 0 45 V operating Vt variation tolerant 9T 18T dual port SRAM March 2011 pp 1 4 doi 10 1109 ISQED 2011 5770728 S2CID 6397769 United States Patent 6975532 Quasi static random access memory Area Optimization in 6T and 8T SRAM Cells Considering Vth Variation in Future Processes MORITA et al E90 C 10 1949 IEICE Transactions on Electronics Archived from the original on 2008 12 05 Preston Ronald P 2001 14 Register Files and Caches PDF The Design of High Performance Microprocessor Circuits IEEE Press p 290 Archived from the original PDF on 2013 05 09 Retrieved 2013 02 01 United States Patent 6975531 6F2 3 transistor DRAM gain cell 3T iRAM r Technology Kabir Hussain Mohammed Dipu Chan Mansun January 2 2015 SRAM precharge system for reducing write power HKIE Transactions 22 1 1 8 doi 10 1080 1023697X 2014 970761 S2CID 108574841 via CrossRef CiteSeerX CiteSeerX CiteSeerX 10 1 1 119 3735 Walker Andrew February 6 2019 The Race is On EE Times a b Reda Boumchedda May 20 2019 Ultra low voltage and energy efficient SRAM design with new technologies for IoT applications Grenoble Alpes University Retrieved from https en wikipedia org w index php title Static random access memory amp oldid 1222723214, wikipedia, wiki, book, books, library,

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