Semiconductor memory
Semiconductor memory is a digital electronic semiconductor device used for digital data storage, such as computer memory. It typically refers to MOS memory, where data is stored within metal–oxide–semiconductor memory cells on a silicon integrated circuit memory chip. There are numerous different types using different semiconductor technologies. The two main types of random-access memory are static RAM, which uses several transistors per memory cell, and Dynamic random-access memory, which uses a single transistor and MOS capacitor per cell. Non-volatile memory uses floating-gate memory cells, which consist of a single transistor per cell.
Most types of semiconductor memory have the property of random access, which means that it takes the same amount of time to access any memory location, so data can be efficiently accessed in any random order. This contrasts with data storage media such as hard disks and CDs which read and write data consecutively and therefore the data can only be accessed in the same sequence it was written. Semiconductor memory also has much faster access times than other types of data storage; a byte of data can be written to or read from semiconductor memory within a few nanoseconds, while access time for rotating storage such as hard disks is in the range of milliseconds. For these reasons it is used for main computer memory, to hold data the computer is currently working on, among other uses.
, semiconductor memory chips sell annually, accounting for % of the semiconductor industry. Shift registers, processor registers, data buffers and other small digital registers that have no memory address decoding mechanism are typically not referred to as "memory" although they also store digital data.
Description
In a semiconductor memory chip, each bit of binary data is stored in a tiny circuit called a memory cell consisting of one to several transistors. The memory cells are laid out in rectangular arrays on the surface of the chip. The 1-bit memory cells are grouped in small units called words which are accessed together as a single memory address. Memory is manufactured in word length that is usually a power of two, typically N=1, 2, 4 or 8 bits.Data is accessed by means of a binary number called a memory address applied to the chip's address pins, which specifies which word in the chip is to be accessed. If the memory address consists of M bits, the number of addresses on the chip is 2M, each containing an N bit word. Consequently, the amount of data stored in each chip is N2M bits. The memory storage capacity for M number of address lines is given by 2M, which is usually in power of two: 2, 4, 8, 16, 32, 64, 128, 256 and 512 and measured in kibibits, mebibits, gibibits or tebibits, etc. the largest semiconductor memory chips hold a few gibibits of data, but higher capacity memory is constantly being developed. By combining several integrated circuits, memory can be arranged into a larger word length and/or address space than what is offered by each chip, often but not necessarily a power of two.
The two basic operations performed by a memory chip are "read", in which the data contents of a memory word is read out, and "write" in which data is stored in a memory word, replacing any data that was previously stored there. To increase data rate, in some of the latest types of memory chips such as DDR SDRAM multiple words are accessed with each read or write operation.
In addition to standalone memory chips, blocks of semiconductor memory are integral parts of many computer and data processing integrated circuits. For example, the microprocessor chips that run computers contain cache memory to store instructions awaiting execution.
Types
Volatile memory
loses its stored data when the power to the memory chip is turned off. However it can be faster and less expensive than non-volatile memory. This type is used for the main memory in most computers, since data is stored on the hard disk while the computer is off. Major types are:RAM This has become a generic term for any semiconductor memory that can be written to, as well as read from, in contrast to ROM ', which can only be read. All semiconductor memory, not just RAM, has the property of random access.
Non-volatile memory
preserves the data stored in it during periods when the power to the chip is turned off. Therefore, it is used for the memory in portable devices, which don't have disks, and for removable memory cards among other uses. Major types are: Non-volatile semiconductor memory stores data in floating-gate memory cells, which each consist of a floating-gate MOSFET.- ROM This is designed to hold permanent data, and in normal operation is only read from, not written to. Although many types can be written to, the writing process is slow and usually all the data in the chip must be rewritten at once. It is usually used to store system software which must be immediately accessible to the computer, such as the BIOS program which starts the computer, and the software for portable devices and embedded computers such as microcontrollers.
- * MROM In this type the data is programmed into the chip during manufacture, so it is only used for large production runs. It cannot be rewritten with new data.
- * PROM In this type the data is written into the chip before it is installed in the circuit, but it can only be written once. The data is written by plugging the chip into a device called a PROM programmer.
- * EPROM In this type the data in it can be rewritten by removing the chip from the circuit board, exposing it to an ultraviolet light to erase the existing data, and plugging it into a PROM programmer. The IC package has a small transparent "window" in the top to admit the UV light. It is often used for prototypes and small production run devices, where the program in it may have to be changed at the factory.
- * EEPROM In this type the data can be rewritten electrically, while the chip is on the circuit board, but the writing process is slow. This type is used to hold firmware, the low level microcode which runs hardware devices, such as the BIOS program in most computers, so that it can be updated.
- NVRAM
- * FRAM One type of nonvolatile RAM.
- Flash memory In this type the writing process is intermediate in speed between EEPROMS and RAM memory; it can be written to, but not fast enough to serve as main memory. It is often used as a semiconductor version of a hard disk, to store files. It is used in portable devices such as PDAs, USB flash drives, and removable memory cards used in digital cameras and cellphones.
History
MOS memory
The advent of the MOSFET, invented by Mohamed M. Atalla and Dawon Kahng at Bell Labs in 1959, enabled the practical use of metal–oxide–semiconductor transistors as memory cell storage elements, a function previously served by magnetic cores in computer memory. MOS memory was developed by John Schmidt at Fairchild Semiconductor in 1964. In addition to higher performance, MOS memory was cheaper and consumed less power than magnetic-core memory. This led to MOSFETs eventually replacing magnetic cores as the standard storage elements in computer memory.In 1965, J. Wood and R. Ball of the Royal Radar Establishment proposed digital storage systems that use CMOS memory cells, in addition to MOSFET power devices for the power supply, switched cross-coupling, switches and delay line storage. The development of silicon-gate MOS integrated circuit technology by Federico Faggin at Fairchild in 1968 enabled the production of MOS memory chips. NMOS memory was commercialized by IBM in the early 1970s. MOS memory overtook magnetic core memory as the dominant memory technology in the early 1970s.
The term "memory" when used with reference to computers most often refers to volatile random-access memory. The two main types of volatile RAM are static random-access memory and dynamic random-access memory. Bipolar SRAM was invented by Robert Norman at Fairchild Semiconductor in 1963, followed by the development of MOS SRAM by John Schmidt at Fairchild in 1964. SRAM became an alternative to magnetic-core memory, but required six MOS transistors for each bit of data. Commercial use of SRAM began in 1965, when IBM introduced their SP95 SRAM chip for the System/360 Model 95.
Toshiba introduced bipolar DRAM memory cells for its Toscal BC-1411 electronic calculator in 1965. While it offered improved performance over magnetic-core memory, bipolar DRAM could not compete with the lower price of the then dominant magnetic-core memory. MOS technology is the basis for modern DRAM. In 1966, Dr. Robert H. Dennard at the IBM Thomas J. Watson Research Center was working on MOS memory. While examining the characteristics of MOS technology, he found it was capable of building capacitors, and that storing a charge or no charge on the MOS capacitor could represent the 1 and 0 of a bit, while the MOS transistor could control writing the charge to the capacitor. This led to his development of a single-transistor DRAM memory cell. In 1967, Dennard filed a patent under IBM for a single-transistor DRAM memory cell, based on MOS technology. This led to the first commercial DRAM IC chip, the Intel 1103, in October 1970. Synchronous dynamic random-access memory later debuted with the Samsung KM48SL2000 chip in 1992.
The term "memory" is also often used to refer to non-volatile memory, specifically flash memory. It has origins in read-only memory. Programmable read-only memory was invented by Wen Tsing Chow in 1956, while working for the Arma Division of the American Bosch Arma Corporation. In 1967, Dawon Kahng and Simon Sze of Bell Labs proposed that the floating gate of a MOS semiconductor device could be used for the cell of a reprogrammable read-only memory, which led to Dov Frohman of Intel inventing EPROM in 1971. EEPROM was developed by Yasuo Tarui, Yutaka Hayashi and Kiyoko Naga at the Electrotechnical Laboratory in 1972. Flash memory was invented by Fujio Masuoka at Toshiba in the early 1980s. Masuoka and colleagues presented the invention of NOR flash in 1984, and then NAND flash in 1987. Toshiba commercialized NAND flash memory in 1987.
Applications
| MOS memory type | MOS memory cell | Applications | |
| Static random-access memory | SRAM | MOSFETs | Cache memory, cell phones, eSRAM, mainframes, multimedia computers, networking, personal computers, servers, supercomputers, telecommunications, workstations, DVD disk buffer, data buffer, nonvolatile BIOS memory |
| Dynamic random-access memory | DRAM | MOSFET, MOS capacitor | Camcorders, embedded logic, eDRAM, graphics card, hard disk drive, networks, personal computers, personal digital assistants, printers, main computer memory, desktop computers, servers, solid-state drives, video memory, framebuffer memory |
| Ferroelectric random-access memory | FRAM | MOSFET, MOS capacitor | Non-volatile memory, radio-frequency identification, smart cards |
| Read-only memory | ROM | MOSFET | Character generators, electronic musical instruments, laser printer fonts, video game ROM cartridges, word processor dictionary data |
| Erasable programmable read-only memory | EPROM | Floating-gate MOSFET | CD-ROM drives, embedded memory, code storage, modems |
| Electrically erasable programmable read-only memory | EEPROM | Floating-gate MOSFET | Anti-lock braking systems, air bags, car radios, cell phones, consumer electronics, cordless telephones, disk drives, embedded memory, flight controllers, military technology, modems, pagers, printers, set-top box, smart cards |
| Flash memory | Flash | Floating-gate MOSFET | ATA controllers, battery-powered applications, telecommunications, code storage, digital cameras, MP3 players, portable media players, BIOS memory, USB flash drive, digital TV, e-books, memory cards, mobile devices, set-top box, smartphones, solid-state drives, tablet computers |
| Non-volatile random-access memory | NVRAM | Floating-gate MOSFETs | Medical equipment, spacecraft |