DDR3 Memory

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DDR3 SDRAM is a performance evolution and enhancement of SDRAM technology starting at 800 Mb/s, which is the highest data rate supported by most DDR2 SDRAMs. DDR3 SDRAMs support six levels of data rates and clock speeds (See Table 3). DDR3-800/1066/1333 SDRAMs became available in 2007, while DDR3 -1600/1866 SDRAMs are expected in 2008 and DDR3 -2133 SDRAMs in 2009.

DDR3 -1066 SDRAM uses less power than DDR2-800 SDRAM because the DDR3 SDRAM operating voltage is 1.5 volts, which is 83% of DDR2 SDRAM’s 1.8 volts. Also, the DDR3 SDRAM data DQ drivers are at higher 34 ohms impedance than DDR2 SDRAM’s lower 18 ohms impedance.

DDR3 SDRAM will start with 512 Mb of memory and will grow to 8 Gb memory in the future. Just like DDR2 SDRAM, DDR3 SDRAM data output configurations include x4, x8 and x16. DDR3 SDRAM has eight banks where as DDR2 SDRAM has four or eight depending upon the memory size.

                            

                                              DDR3 SLOTS

DDR3 SDRAM                 Data Rate                      Memory Clock

DDR3-800                      800 Mb/s/pin                         400 MHz

DDR3-1066                  1066Mb/s/pin                          533 MHz

DDR3-1333                  1333Mb/s/pin                          667 MHz

DDR3-1600                  1600 Mb/s/pin                         800 MHz

DDR3-1866                  1866Mb/s/pin                          933 MHz

DDR3-2133                  2133Mb/s/pin                        1066 MHz

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SDRAM memory

SDRAM MEMORY 

• 168-pin DIMM, used for SDR SDRAM (less frequently for FPM/EDO DRAM in workstations/servers, may be 3.3 or 5 V)
• 

168-pin SDRAM

On the bottom edge of 168-pin DIMMs there are two notches, and the location of each notch determines a particular feature of the module. The first notch is the DRAM key position, which represents RFU (reserved future use), registered, and unbuffered DIMM types (left, middle and right position, respectively). The second notch is the voltage key position, which represents 5.0 V, 3.3 V, and RFU DIMM types

Three SDRAM DIMM slots on a computer motherboard

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SDR SDRAM   SPEEDS

 Chip               Module             Effective Clock           Voltage    

SDR-66             PC-66                       66 MHz                         3.3 V

SDR-100          PC-100                   100 MHz                         3.3 V

SDR-133          PC-133                    133 MHz                          3.3 V

Synchronous dynamic random access memory (SDRAM) is dynamic random access memory (DRAM) that is synchronized with the system bus. Classic DRAM has an asynchronous interface, which means that it responds as quickly as possible to changes in control inputs. SDRAM has a synchronous interface, meaning that it waits for a clock signal before responding to control inputs and is therefore synchronized with the computer’s system bus. The clock is used to drive an internal finite state machine that pipelines incoming commands. The data storage area is divided into several banks, allowing the chip to work on several memory access commands at a time, interleaved among the separate banks. This allows higher data access rates than an asynchronous DRAM.

Pipelining means that the chip can accept a new command before it has finished processing the previous one. In a pipelined write, the write command can be immediately followed by another command, without waiting for the data to be written to the memory array. In a pipelined read, the requested data appears after a fixed number of clock cycles after the read command (latency), clock cycles during which additional commands can be sent. (This delay is called the latency and is an important performance parameter to consider when purchasing SDRAM for a computer.)

SDRAM is widely used in computers; after the original SDRAM, further generations of double data rate RAM have entered the mass market – DDR (also known as DDR1), DDR2, DDR3 and DDR4, with the latest generation (DDR4) released in second half of 2014.

Originally simply known as SDRAM, single data rate SDRAM can accept one command and transfer one word of data per clock cycle. Typical clock frequencies are 100 and 133 MHz. Chips are made with a variety of data bus sizes (most commonly 4, 8 or 16 bits), but chips are generally assembled into 168-pin DIMMs that read or write 64 (non-ECC) or 72 (ECC) bits at a time.

Use of the data bus is intricate and thus requires a complex DRAM controller circuit. This is because data written to the DRAM must be presented in the same cycle as the write command, but reads produce output 2 or 3 cycles after the read command. The DRAM controller must ensure that the data bus is never required for a read and a write at the same time.

Typical SDR SDRAM clock rates are 66, 100, and 133 MHz (periods of 15, 10, and 7.5 ns). Clock rates up to 150 MHz were available for performance enthusiasts.

Types of ram memory

Memory Terminology: This is a simplified overview of RAM terms and definitions

100 pin memory
Used primarily in laser printers, 100 pin SIMM memory is not compatible with other formats.

CAS Latency:
To oversimplify a complex discussion, the main timing of a RAM module is described by a CAS (Column Address Strobe) Latency value. This is the length of time that a RAM module needs between serving one request and when it is “recharged” and able to take the next request. All else being equal, and if the motherboard can make use of faster latencies, the lower the CAS Latency value the faster the RAM can respond.

Typical DDR CAS values are CL3, CL2.5 and CL2 . There are other latency measurements but CAS Latency is the most important.

In older SDRAM (PC66, PC100, PC133) , a CL2 module is not always faster than a CL3 module – the effective speed is determined by the memory controller on the motherboard of the computer, and in some cases a CL3 module matches an older motherboard’s timing better and performs faster than a CL2 module.

Non-Synchronus memory isn’t measured the same way – it has a memory response speed in nanoseconds, and the computer waits for the RAM chip to be ready. Synchronous RAM, in contrast, synchronizes its operations to the computer’s memory buss clock.

SDRAM can be CAS 2 or CAS 3

DDR RAM is normally CAS Latency 2.5 for PC2700 modules and CL3 for PC3200 modules. Premium modules are available with CL2.5 or CL2.0 on higher-capacity PC3200 modules. (DDR make two operations per clock cycle, which is why it can have “half” of a tick)

DDR-2 RAM is normally CAS Latency 4 (DDR2-533), CAS Latency 5 (DDR2-667) and CAS Latency 5 0r 6 (DDR2-800). Lower latency RAM is available at higher prices.

DDR-3 RAM has CAS latencies in the range of 7 to 9. This means that the latency penalty versus DDR-2 RAM negates some of the advantage of DDR-3 running at higher clock speeds. This is expected to improve over time.

DDR – Dual Data Rate RAM
Can be packaged in both DIMM (184-pin for Desktops) and SO-DIMM (200-pin for laptops) forms. Speeds are PC2100 (266 MHz) PC2700 (333 MHz) and PC3200 (400 MHz) DDR . The standards for speeds higher than PC3200 are not finalized, although some manufacturers offer “PC3700″ “PC4000″ and up DDR modules as a marketing designation.

DDR-2 A format that is faster than DDR. DDR and DDR-2 are not compatible with each other. Designations are PC2-5300 (DDR2-667 MHz), PC2-4200 (DDR2-533 MHz, also called by some manufacturers PC4300), and PC2-6400 (DDR2-800). Available in both DIMM and SODIMM packages. Faster speed RAM is available at higher prices.

DDR-3
DDR-3 is now the primary RAM type for new desktop and laptop machines and motherboards. DDR, DDR-2 and DDR-3 are not compatible with each other. Some early DDR3 motherboards have sockets for both DDR-2 and DDR-3 memory, however the two formats cannot be combined at the same time.

DDR-4
New type of memory.There are a lot of deeply technical aspects to DDR4, but we won’t dive that far. The two key improvements in DDR4 are power consumption and data transfer speed, thanks to the development of an all-new bus.

DDR4 memory will deliver significant benefits in terms of performance and power consumption. 

DDR3 generally requires 1.5 volts of electrical power to operate. DDR4 needs 20 percent less—just 1.2 volts. DDR4 also supports a new, deep power-down mode that will allow the host device to go into standby without needing to refresh its memory. Deep power-down mode is expected to reduce standby power consumption by 40- to 50 percent.