DDR-400 memory with
heat spreaders )
Modules To increase memory capacity and bandwidth, chips are combined on a module. For instance, the 64-bit data bus for DIMM requires eight 8-bit chips, addressed in parallel. Multiple chips with common address lines are called a
memory rank. The term was introduced to avoid confusion with chip internal
rows and
banks. A memory module may bear more than one rank. The term
sides would also be confusing because it incorrectly suggests the physical placement of chips on the module. All ranks are connected to the same memory bus (address + data). The
chip select signal is used to issue commands to specific rank. Adding modules to the single memory bus creates additional electrical load on its drivers. To mitigate the resulting bus signaling rate drop and overcome the
memory bottleneck, new
chipsets employ the
multi-channel architecture.
Note: All items listed above are specified by
JEDEC as JESD79F. All RAM data rates in-between or above these listed specifications are not standardized by JEDEC – often they are simply manufacturer optimizations using tighter tolerances or overvolted chips. The package sizes in which DDR SDRAM is manufactured are also standardized by JEDEC. There is no architectural difference between DDR SDRAM modules. Modules are instead designed to run at different clock frequencies: for example, a PC-1600 module is designed to run at , and a PC-2100 is designed to run at . A module's clock speed designates the data rate at which it is guaranteed to perform, hence it is guaranteed to run at lower (
underclocking) and can possibly run at higher (
overclocking) clock rates than those for which it was made. DDR SDRAM modules for desktop computers,
dual in-line memory modules (DIMMs), have 184 pins (as opposed to 168 pins on SDRAM, or 240 pins on DDR2 SDRAM), and can be differentiated from SDRAM DIMMs by the number of notches (DDR SDRAM has one, SDRAM has two). DDR SDRAM for notebook computers,
SO-DIMMs, have 200 pins, which is the same number of pins as DDR2 SO-DIMMs. These two specifications are notched very similarly and care must be taken during insertion if unsure of a correct match. Most DDR SDRAM operates at a voltage of 2.5 V, compared to 3.3 V for SDRAM. This can significantly reduce power consumption. Chips and modules with the DDR-400/PC-3200 standard have a nominal voltage of 2.6 V. JEDEC Standard No. 21–C defines three possible operating voltages for 184 pin DDR, as identified by the key notch position relative to its centreline. Page 4.5.10-7 defines 2.5V (left), 1.8V (centre), TBD (right), while page 4.20.5–40 nominates 3.3V for the right notch position. The orientation of the module for determining the key notch position is with 52 contact positions to the left and 40 contact positions to the right. Increasing the operating voltage slightly can increase maximum speed but at the cost of higher power dissipation and heating, and at the risk of malfunctioning or damage. ;Capacity ;Number of DRAM devices: The number of chips is a multiple of 8 for non-
ECC modules and a multiple of 9 for ECC modules. Chips can occupy one side (
single sided) or both sides (
dual sided) of the module. The maximal number of chips per DDR module is 36 (9×4) for ECC and 32 (8x4) for non-ECC. ;ECC vs non-ECC: Modules that have
error-correcting code are labeled as
ECC. Modules without error correcting code are labeled
non-ECC. ;Timings:
CAS latency (CL), clock cycle time (tCK), row cycle time (tRC), refresh row cycle time (tRFC), row active time (tRAS). ;Buffering:
Registered (or buffered) vs
unbuffered. ;Packaging: Typically
DIMM or
SO-DIMM. ;Power consumption: A test with DDR and DDR2 RAM in 2005 found that average power consumption appeared to be of the
order of 1–3 W per 512 MB module; this increases with clock rate and when in use rather than idling. A manufacturer has produced calculators to estimate the power used by various types of RAM. Module and chip characteristics are inherently linked. Total module capacity is a product of one chip's capacity and the number of chips. ECC modules multiply it by because they use 1 bit per byte (8 bits) for error correction. A module of any particular size can therefore be assembled either from 32 small chips (36 for ECC memory), or 16(18) or 8(9) bigger ones. DDR memory bus width per channel is 64 bits (72 for ECC memory). Total module bit width is a product of bits per chip and number of chips. It also equals number of ranks (rows) multiplied by DDR memory bus width. Consequently, a module with a greater number of chips or using ×8 chips instead of ×4 will have more ranks. This example compares different real-world server memory modules with a common size of 1 GB. One should definitely be careful buying 1 GB memory modules, because all these variations can be sold under one price position without stating whether they are ×4 or ×8, single- or dual-ranked. There is a common belief that number of module ranks equals number of sides. As above data shows, this is not true. One can also find 2-side/1-rank modules. One can even think of a 1-side/2-rank memory module having 16(18) chips on single side ×8 each, but it is unlikely such a module was ever produced.
Chip characteristics of a Samsung DDR-SDRAM 64MBit package ;DRAM density: Size of the chip is measured in
megabits. Most motherboards recognize only 1 GB modules if they contain
64M×8 chips (
low density). If
128M×4 (
high density) 1 GB modules are used, they most likely will not work. The
JEDEC standard allows
128M×4 only for registered modules designed specifically for servers, but some generic manufacturers do not comply. ;Organization: The notation like
64M×4 means that the memory matrix has 64 million (the product of
banks x
rows x
columns) 4-bit storage locations. There are
×4, ×8, and
×16 DDR chips. The
×4 chips allow the use of advanced error correction features like
Chipkill,
memory scrubbing and Intel SDDC in server environments, while the
×8 and
×16 chips are somewhat less expensive.
x8 chips are mainly used in desktops/notebooks but are making an entry into the server market. There are normally 4 banks and only one row can be active in each bank.
Double data rate (DDR) SDRAM specification From Ballot JCB-99-70, and modified by numerous other Board Ballots, formulated under the cognizance of Committee JC-42.3 on DRAM Parametrics. Standard No. 79 Revision Log: • Release 1, June 2000 • Release 2, May 2002 • Release C, March 2003 – JEDEC Standard No. 79C. "This comprehensive standard defines all required aspects of 64Mb through 1Gb DDR SDRAMs with X4/X8/X16 data interfaces, including features, functionality, ac and dc parametrics, packages and pin assignments. This scope will subsequently be expanded to formally apply to x32 devices, and higher density devices as well."
Organization PC3200 is DDR SDRAM designed to operate at 200 MHz using DDR-400 chips with a bandwidth of 3,200 MB/s. Because PC3200 memory transfers data on both the rising and falling clock edges, its effective clock rate is 400 MHz. 1 GB PC3200 non-ECC modules are usually made with 16 512 Mbit chips, 8 on each side (512 Mbits × 16 chips) / (8 bits (per byte)) = 1,024 MB. The individual chips making up a 1 GB memory module are usually organized as 226 8-bit words, commonly expressed as 64M×8. Memory manufactured in this way is low-density RAM and is usually compatible with any motherboard specifying PC3200 DDR-400 memory. == Generations ==