Ddr4 Ram Slot Name
2021年5月23日Register here: http://gg.gg/uoz03
*Memory Ram Ddr4
*Ddr4 Ram Slot Name Plates
*Ddr4 Ram Slot Name Holders
*Ddr4 Memory Speed
I’m upgrading to Skylake and got 2 sticks of 8gb DDR4 to go with the new Z170 mobo. I’ve read in various places that the dual channel slots furthest from the CPU (2+4) are somehow better to use than slots 1+3 if you only have two sticks. Kingston HyperX Fury Black. As one of the oldest memory manufacturers on the market, Kingston.
If you intend to upgrade the RAM on any of your computers and said machines are powered by DDR4, it’s time to bite the bullet and do the upgrade. While we can’t literally guarantee that RAM prices won’t continue to decline, they’ve fallen far enough to qualify as an automatically excellent value, especially if you scrimped on RAM 18 months ago to avoid paying what were then very high prices. Jade elephant slot machine.
We’ve been watching RAM prices for roughly 17 months now, and have seen them decline from $180 for 16GB of DDR4-3200 to just $56 today. That’s a drop of nearly 70 percent, and it’s one reason we’re comfortable giving a blanket recommendation to anyone on the upgrade fence. You might save another $5 to $10 if prices continue to drop, but you aren’t going to save another $50 on DDR4-3200.
The rock-bottom pricing on high-clock DDR4 that we saw at the end of May surprised us, and it’s not surprising to see prices rising again at the top of the stack. That’s not to say that RAM costs are going to start increasing across the board. The May values we recorded were genuinely lower than we expected and may have represented a temporary blip. Regardless, however, we know how this cycle will end, because RAM introductions and phase-outs have followed more or less the same price cycle for at least the last 20 years, as this graph from CamelCamelCamel illustrates:
This graph charts the price of this specific DDR3 module from 2012 – 2019, and it’s an excellent illustration of the boom-and-bust cycle in DRAM manufacturing. Just as there used to be a dozen and more companies engaged in leading-edge foundry manufacturing, there used to be considerably more companies engaged in DRAM manufacturing. Technically, there are still a lot of companies in DRAM, but three firms — Samsung, SK Hynix, and Micron — have 95.6 percent of the market.
The reason these companies got into NAND manufacturing in the first place was partly to buffer the impact of the boom-and-bust DRAM cycle, which drove plenty of corporations out of the market. With NAND undergoing simultaneous price contraction, that policy hasn’t automatically worked out swimmingly this cycle, but it served as a buffer for memory manufacturers earlier this decade and may do so again if the downturns aren’t simultaneous.
Either way, it’s an absolute given that RAM prices will rise again. Even if they remain low for the next year, they’ll inevitably rise when DDR5 rolls out. Manufacturers forced into low profit margins or outright losses by DRAM prices use the introduction of new standards to recoup their profits and pay for the next round of investments required for future memory standards. This boom-and-bust cycle is what drove companies out of the RAM business in the first place — it’s difficult to predict and an unforgiving environment to operate in while simultaneously making long-term technology and capacity investments.How Much DRAM Do You Need?
There was a time when the DRAM needs of desktop and laptop computing were accelerating much more quickly than they are today. In 2008, when Intel launched the X59 motherboard platform and its triple-channel memory configuration, 6GB-12GB RAM kits became much more common, with 3-6 sticks of DRAM. The return of dual-channel configurations meant 8-16GB became standard a few years later, and that’s more or less where most applications and users still are.
Don’t mistake me. There are applications that can consume more than this amount of RAM. One of the rules of reporting is that as soon as you offer a claim on how much RAM anyone needs, someone on the internet is legally required to bring up Bill Gates’ quote on 640KB of RAM being enough for anybody, while someone else is required to explain how they know about someone who is using 2x – 8x more RAM than whatever amount the author has just stated should be sufficient for most users, as though this objective fact invalidated the point.
If your goal is to hit the highest RAM clocks possible, a smaller pool of single-sided DIMMs is more likely to help you do that than filling every DIMM slot. If you know you need a high RAM system, then obviously you’ve got a specific requirement that overrides more general requirements. Mobile users who prioritize battery life should be aware that adding RAM also inevitably increases power consumption — if your goal is to maximize battery life, you’ll want to pay attention to how much RAM you actually need rather than just stuffing a laptop with as much as it can hold.
Personally, I’d call 8GB acceptable, 16GB preferred, and 32GB “reasonable” for an average user if your goal is to make sure you never have to care about putting RAM in the system again. 16-32GB should be enough to keep a system on par with the consoles Microsoft and Sony are working on, and that’s as reasonable a benchmark as any for a gamer to target. Basic blackjack strategy chart. I have yet to see any benefit in typical consumer applications between 16GB and 32GB of RAM, and anything over 32GB is overkill for normal desktop users. There are professional users and workstation applications that can use more RAM than this, but if you’re one of those users, you already know it and don’t need me to tell you.
Regardless of the total RAM you target, if you’ve been holding off on buying, now is the time. The one guarantee is that prices will increase.
Now Read:Two types of DIMMs: a 168-pin SDRAM module (top) and a 184-pin DDR SDRAM module (bottom). The SDRAM module has two notches (rectangular cuts or incisions) on the bottom edge, while the DDR1 SDRAM module has only one. Also, each module has eight RAM chips, but the lower one has an unoccupied space for the ninth chip; this space is occupied in ECC DIMMsThree SDRAM DIMM slots on a computer motherboard
A DIMM or dual in-line memory module, commonly called a RAM stick, comprises a series of dynamic random-access memoryintegrated circuits. These modules are mounted on a printed circuit board and designed for use in personal computers, workstations and servers. DIMMs began to replace SIMMs (single in-line memory modules) as the predominant type of memory module as IntelP5-based Pentium processors began to gain market share.
While the contacts on SIMMs on both sides are redundant, DIMMs have separate electrical contacts on each side of the module. Another difference is that standard SIMMs have a 32-bit data path, while standard DIMMs have a 64-bit data path. Since Intel’s Pentium, many processors have a 64-bit bus width, requiring SIMMs installed in matched pairs in order to populate the data bus. The processor would then access the two SIMMs in parallel. DIMMs were introduced to eliminate this disadvantage.Variants[edit]
Variants of DIMM slots support DDR, DDR2, DDR3, DDR4 and DDR5 RAM.
Common types of DIMMs include the following:SDRAMSDR
SDRAMDDR
SDRAMDDR2
SDRAMDDR3
SDRAMDDR4
SDRAMDDR5
SDRAM Jeux gratuits casino en ligne.FPM DRAM
and EDO DRAMFB-DIMM
DRAMDIMM100-pin168-pin184-pin240-pin[a]288-pin[a]168-pin240-pinSO-DIMMN/A144-pin200-pin[a]204-pin260-pin72-pin/144-pinN/AMicroDIMMN/A144-pin172-pin214-pinN/AN/A
70 to 200 pins
*72-pin SO-DIMM (not the same as a 72-pin SIMM), used for FPM DRAM and EDO DRAM
*100-pin DIMM, used for printer SDRAM
*144-pin SO-DIMM, used for SDR SDRAM (less frequently for DDR2 SDRAM)
*168-pin DIMM, used for SDR SDRAM (less frequently for FPM/EDO DRAM in workstations/servers, may be 3.3 or 5 V)
*172-pin MicroDIMM, used for DDR SDRAM
*184-pin DIMM, used for DDR SDRAM
*200-pin SO-DIMM, used for DDR SDRAM and DDR2 SDRAM
*200-pin DIMM, used for FPM/EDO DRAM in some Sun workstations and servers.
201 to 300 pins
*204-pin SO-DIMM, used for DDR3 SDRAM
*214-pin MicroDIMM, used for DDR2 SDRAM
*240-pin DIMM, used for DDR2 SDRAM, DDR3 SDRAM and FB-DIMM DRAM
*244-pin MiniDIMM, used for DDR2 SDRAM
*260-pin SO-DIMM, used for DDR4 SDRAM
*260-pin SO-DIMM, with different notch position than on DDR4 SO-DIMMs, used for UniDIMMs that can carry either DDR3 or DDR4 SDRAM
*278-pin DIMM, used for HP high density SDRAM.
*288-pin DIMM, used for DDR4 SDRAM and DDR5 SDRAM[1]168-pin SDRAM[edit]Notch positions on DDR (top) and DDR2 (bottom) DIMM modules
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 (order is the same as above).DDR DIMMs[edit]8 GB DDR4-2133 ECC 1.2 V RDIMMs
DDR, DDR2, DDR3, DDR4 and DDR5 all have different pin counts and/or different notch positions. As of August, 2014, DDR4 SDRAM is a modern emerging type of dynamic random access memory (DRAM) with a high-bandwidth (’double data rate’) interface, and has been in use since 2013. It is the higher-speed successor to DDR, DDR2 and DDR3. DDR4 SDRAM is neither forward nor backward compatible with any earlier type of random access memory (RAM) because of different signalling voltages, timings, as well as other differing factors between the technologies and their implementation.SPD EEPROM[edit]
A DIMM’s capacity and other operational parameters may be identified with serial presence detect (SPD), an additional chip which contains information about the module type and timing for the memory controller to be configured correctly. The SPD EEPROM connects to the System Management Bus and may also contain thermal sensors (TS-on-DIMM).[2]Error correction[edit]
ECC DIMMs are those that have extra data bits which can be used by the system memory controller to detect and correct errors. There are numerous ECC schemes, but perhaps the most common is Single Error Correct, Double Error Detect (SECDED) which uses an extra byte per 64-bit word. ECC modules usually carry a multiple of 9 instead of a multiple of 8 chips.Ranking[edit]
Sometimes memory modules are designed with two or more independent sets of DRAM chips connected to the same address and data buses; each such set is called a rank. Ranks that share the same slot, only one rank may be accessed at any given time; it is specified by activating the corresponding rank’s chip select (CS) signal. The other ranks on the module are deactivated for the duration of the operation by having their corresponding CS signals deactivated. DIMMs are currently being commonly manufactured with up to four ranks per module. Consumer DIMM vendors have recently begun to distinguish between single and dual ranked DIMMs.
After a memory word is fetched, the memory is typically inaccessible for an extended period of time while the sense amplifiers are charged for access of the next cell. By interleaving the memory (e.g. cells 0, 4, 8, etc. are stored together in one rank), sequential memory accesses can be performed more rapidly because sense amplifiers have 3 cycles of idle time for recharging, between accesses.
DIMMs are often referred to as ’single-sided’ or ’double-sided’ to describe whether the DRAM chips are located on one or both sides of the module’s printed circuit board (PCB). However, these terms may cause confusion, as the physical layout of the chips does not necessarily relate to how they are logically organized or accessed.
JEDEC decided that the terms ’dual-sided’, ’double-sided’, or ’dual-banked’ were not correct when applied to registered DIMMs (RDIMMs).Organization[edit]
Most DIMMs are built using ’×4’ (’by four’) or ’×8’ (’by eight’) memory chips with nine chips per side; ’×4’ and ’×8’ refer to the data width of the DRAM chips in bits.
In the case of ’×4’ registered DIMMs, the data width per side is 36 bits; therefore, the memory controller (which requires 72 bits) needs to address both sides at the same time to read or write the data it needs. In this case, the two-sided module is single-ranked. For ’×8’ registered DIMMs, each side is 72 bits wide, so the memory controller only addresses one side at a time (the two-sided module is dual-ranked).
The above example applies to ECC memory that stores 72 bits instead of the more common 64. There would also be one extra chip per group of eight, which is not counted.Speeds[edit]
For various technologies, there are certain bus and device clock frequencies that are standardized; there is also a decided nomenclature for each of these speeds for each type.
DIMMs based on Single Data Rate (SDR) DRAM have the same bus frequency for data, address and control lines. DIMMs based on Double Data Rate (DDR) DRAM have data but not the strobe at double the rate of the clock; this is achieved by clocking on both the rising and falling edge of the data strobes. Power consumption and voltage gradually became lower with each generation of DDR-based DIMMs.
Another influence is Column Access Strobe (CAS) latency, or CL which affects memory access speed. This is the delay time between the READ command and the moment data is available. See main article CAS/CL SDR SDRAM DIMMsChipModuleEffective ClockTransfer rateVoltageSDR-66PC-6666 MHz66 MT/s3.3 VSDR-100PC-100100 MHz100 MT/s3.3 VSDR-133PC-133133 MHz133 MT/s3.3 VDDR SDRAM (DDR1) DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR-200PC-1600100 MHz100 MHz200 MT/s2.5 VDDR-266PC-2100133 MHz133 MHz266 MT/s2.5 VDDR-333PC-2700166 MHz166 MHz333 MT/s2.5 VDDR-400PC-3200200 MHz200 MHz400 MT/s2.5 VDDR2 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR2-400PC2-3200200 MHz200 MHz400 MT/s1.8 VDDR2-533PC2-4200266 MHz266 MHz533 MT/s1.8 VDDR2-667PC2-5300333 MHz333 MHz667 MT/s1.8 VDDR2-800PC2-6400400 MHz400 MHz800 MT/s1.8 VDDR2-1066PC2-8500533 MHz533 MHz1066 MT/s1.8 VDDR3 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR3-800PC3-6400400 MHz400 MHz800 MT/s1.5 VDDR3-1066PC3-8500533 MHz533 MHz1066 MT/s1.5 VDDR3-1333PC3-10600667 MHz667 MHz1333 MT/s1.5 VDDR3-1600PC3-12800800 MHz800 MHz1600 MT/s1.5 VDDR3-1866PC3-14900933 MHz933 MHz1866 MT/s1.5 VDDR3-2133PC3-170001066 MHz1066 MHz2133 MT/s1.5 VDDR3-2400PC3-192001200 MHz1200 MHz2400 MT/s1.5 VDDR4 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR4-1600PC4-12800800 MHz800 MHz1600 MT/s1.2 VDDR4-1866PC4-14900933 MHz933 MHz1866 MT/s1.2 VDDR4-2133PC4-170001066 MHz1066 MHz2133 MT/s1.2 VDDR4-2400PC4-192001200 MHz1200 MHz2400 MT/s1.2 VDDR4-2666PC4-213001333 MHz1333 MHz2666 MT/s1.2 VDDR4-3200PC4-256001600 MHz1600 MHz3200 MT/s1.2 VForm factors[edit]
Several form factors are commonly used in DIMMs. Single Data Rate Synchronous DRAM (SDR SDRAM) DIMMs were primarily manufactured in 1.5 inches (38 mm) and 1.7 inches (43 mm) heights. When 1U rackmount servers started becoming popular, these form factor registered DIMMs had to plug into angled DIMM sockets to fit in the 1.75 inches (44 mm) high box. To alleviate this issue, the next standards of DDR DIMMs were created with a ’low profile’ (LP) height of around 1.2 inches (30 mm). These fit into vertical DIMM sockets for a 1U platform.
With the advent of blade servers, angled slots have once again become common in order to accommodate LP form factor DIMMs in these space-constrained boxes. This led to the development of the Very Low Profile (VLP) form factor DIMM with a height of around 0.72 inches (18 mm). The DDR3 JEDEC standard for VLP DIMM height is around 0.740 inches (18.8 mm). These will fit vertically in ATCA systems.
Full-height 240-pin DDR2 and DDR3 DIMMs are all specified at a height of around 1.18 inches (30 mm) by standards set by JEDEC. These form factors include 240-pin DIMM, SODIMM, Mini-DIMM and Micro-DIMM.[3]
Full-height 288-pin DDR4 DIMMs are slightly taller than their DDR3 counterparts at 1.23 inches (31 mm). Similarly, VLP DDR4 DIMMs are also marginally taller than their DDR3 equivalent at nearly 0.74 inches (19 mm).[4]
As of Q2 2017, Asus has had a PCI-E based ’DIMM.2’, which has a similar socket to DDR3 DIMMs and is used to put in a module to connect up to two M.2NVMe solid-state drives. However, it cannot use common DDR type ram and does not have much support other than Asus.[5]See also[edit]
*Dual in-line package (DIP)
*Memory geometry – logical configuration of RAM modules (channels, ranks, banks, etc.)
*NVDIMM – non-volatile DIMM
*Rambus in-line memory module (RIMM)
*Single in-line memory module (SIMM)
*Single in-line package (SIP)
*Zig-zag in-line package (ZIP)References[edit]Memory Ram Ddr4
*^Smith, Ryan (2020-07-14). ’DDR5 Memory Specification Released: Setting the Stage for DDR5-6400 And Beyond’. AnandTech. Retrieved 2020-07-15.
*^Temperature Sensor in DIMM memory modules
*^JEDEC MO-269J Whitepaper., accessed Aug. 20, 2014.
*^JEDEC MO-309E Whitepaper., accessed Aug. 20, 2014.
*^ASUS DIMM.2 is a M.2 Riser Card., accessed Jun. 4, 2020.Ddr4 Ram Slot Name PlatesExternal links[edit]Ddr4 Ram Slot Name HoldersWikimedia Commons has media related to DIMM.Ddr4 Memory SpeedRetrieved from ’https://en.wikipedia.org/w/index.php?title=DIMM&oldid=988181755’
Register here: http://gg.gg/uoz03
https://diarynote-jp.indered.space
*Memory Ram Ddr4
*Ddr4 Ram Slot Name Plates
*Ddr4 Ram Slot Name Holders
*Ddr4 Memory Speed
I’m upgrading to Skylake and got 2 sticks of 8gb DDR4 to go with the new Z170 mobo. I’ve read in various places that the dual channel slots furthest from the CPU (2+4) are somehow better to use than slots 1+3 if you only have two sticks. Kingston HyperX Fury Black. As one of the oldest memory manufacturers on the market, Kingston.
If you intend to upgrade the RAM on any of your computers and said machines are powered by DDR4, it’s time to bite the bullet and do the upgrade. While we can’t literally guarantee that RAM prices won’t continue to decline, they’ve fallen far enough to qualify as an automatically excellent value, especially if you scrimped on RAM 18 months ago to avoid paying what were then very high prices. Jade elephant slot machine.
We’ve been watching RAM prices for roughly 17 months now, and have seen them decline from $180 for 16GB of DDR4-3200 to just $56 today. That’s a drop of nearly 70 percent, and it’s one reason we’re comfortable giving a blanket recommendation to anyone on the upgrade fence. You might save another $5 to $10 if prices continue to drop, but you aren’t going to save another $50 on DDR4-3200.
The rock-bottom pricing on high-clock DDR4 that we saw at the end of May surprised us, and it’s not surprising to see prices rising again at the top of the stack. That’s not to say that RAM costs are going to start increasing across the board. The May values we recorded were genuinely lower than we expected and may have represented a temporary blip. Regardless, however, we know how this cycle will end, because RAM introductions and phase-outs have followed more or less the same price cycle for at least the last 20 years, as this graph from CamelCamelCamel illustrates:
This graph charts the price of this specific DDR3 module from 2012 – 2019, and it’s an excellent illustration of the boom-and-bust cycle in DRAM manufacturing. Just as there used to be a dozen and more companies engaged in leading-edge foundry manufacturing, there used to be considerably more companies engaged in DRAM manufacturing. Technically, there are still a lot of companies in DRAM, but three firms — Samsung, SK Hynix, and Micron — have 95.6 percent of the market.
The reason these companies got into NAND manufacturing in the first place was partly to buffer the impact of the boom-and-bust DRAM cycle, which drove plenty of corporations out of the market. With NAND undergoing simultaneous price contraction, that policy hasn’t automatically worked out swimmingly this cycle, but it served as a buffer for memory manufacturers earlier this decade and may do so again if the downturns aren’t simultaneous.
Either way, it’s an absolute given that RAM prices will rise again. Even if they remain low for the next year, they’ll inevitably rise when DDR5 rolls out. Manufacturers forced into low profit margins or outright losses by DRAM prices use the introduction of new standards to recoup their profits and pay for the next round of investments required for future memory standards. This boom-and-bust cycle is what drove companies out of the RAM business in the first place — it’s difficult to predict and an unforgiving environment to operate in while simultaneously making long-term technology and capacity investments.How Much DRAM Do You Need?
There was a time when the DRAM needs of desktop and laptop computing were accelerating much more quickly than they are today. In 2008, when Intel launched the X59 motherboard platform and its triple-channel memory configuration, 6GB-12GB RAM kits became much more common, with 3-6 sticks of DRAM. The return of dual-channel configurations meant 8-16GB became standard a few years later, and that’s more or less where most applications and users still are.
Don’t mistake me. There are applications that can consume more than this amount of RAM. One of the rules of reporting is that as soon as you offer a claim on how much RAM anyone needs, someone on the internet is legally required to bring up Bill Gates’ quote on 640KB of RAM being enough for anybody, while someone else is required to explain how they know about someone who is using 2x – 8x more RAM than whatever amount the author has just stated should be sufficient for most users, as though this objective fact invalidated the point.
If your goal is to hit the highest RAM clocks possible, a smaller pool of single-sided DIMMs is more likely to help you do that than filling every DIMM slot. If you know you need a high RAM system, then obviously you’ve got a specific requirement that overrides more general requirements. Mobile users who prioritize battery life should be aware that adding RAM also inevitably increases power consumption — if your goal is to maximize battery life, you’ll want to pay attention to how much RAM you actually need rather than just stuffing a laptop with as much as it can hold.
Personally, I’d call 8GB acceptable, 16GB preferred, and 32GB “reasonable” for an average user if your goal is to make sure you never have to care about putting RAM in the system again. 16-32GB should be enough to keep a system on par with the consoles Microsoft and Sony are working on, and that’s as reasonable a benchmark as any for a gamer to target. Basic blackjack strategy chart. I have yet to see any benefit in typical consumer applications between 16GB and 32GB of RAM, and anything over 32GB is overkill for normal desktop users. There are professional users and workstation applications that can use more RAM than this, but if you’re one of those users, you already know it and don’t need me to tell you.
Regardless of the total RAM you target, if you’ve been holding off on buying, now is the time. The one guarantee is that prices will increase.
Now Read:Two types of DIMMs: a 168-pin SDRAM module (top) and a 184-pin DDR SDRAM module (bottom). The SDRAM module has two notches (rectangular cuts or incisions) on the bottom edge, while the DDR1 SDRAM module has only one. Also, each module has eight RAM chips, but the lower one has an unoccupied space for the ninth chip; this space is occupied in ECC DIMMsThree SDRAM DIMM slots on a computer motherboard
A DIMM or dual in-line memory module, commonly called a RAM stick, comprises a series of dynamic random-access memoryintegrated circuits. These modules are mounted on a printed circuit board and designed for use in personal computers, workstations and servers. DIMMs began to replace SIMMs (single in-line memory modules) as the predominant type of memory module as IntelP5-based Pentium processors began to gain market share.
While the contacts on SIMMs on both sides are redundant, DIMMs have separate electrical contacts on each side of the module. Another difference is that standard SIMMs have a 32-bit data path, while standard DIMMs have a 64-bit data path. Since Intel’s Pentium, many processors have a 64-bit bus width, requiring SIMMs installed in matched pairs in order to populate the data bus. The processor would then access the two SIMMs in parallel. DIMMs were introduced to eliminate this disadvantage.Variants[edit]
Variants of DIMM slots support DDR, DDR2, DDR3, DDR4 and DDR5 RAM.
Common types of DIMMs include the following:SDRAMSDR
SDRAMDDR
SDRAMDDR2
SDRAMDDR3
SDRAMDDR4
SDRAMDDR5
SDRAM Jeux gratuits casino en ligne.FPM DRAM
and EDO DRAMFB-DIMM
DRAMDIMM100-pin168-pin184-pin240-pin[a]288-pin[a]168-pin240-pinSO-DIMMN/A144-pin200-pin[a]204-pin260-pin72-pin/144-pinN/AMicroDIMMN/A144-pin172-pin214-pinN/AN/A
70 to 200 pins
*72-pin SO-DIMM (not the same as a 72-pin SIMM), used for FPM DRAM and EDO DRAM
*100-pin DIMM, used for printer SDRAM
*144-pin SO-DIMM, used for SDR SDRAM (less frequently for DDR2 SDRAM)
*168-pin DIMM, used for SDR SDRAM (less frequently for FPM/EDO DRAM in workstations/servers, may be 3.3 or 5 V)
*172-pin MicroDIMM, used for DDR SDRAM
*184-pin DIMM, used for DDR SDRAM
*200-pin SO-DIMM, used for DDR SDRAM and DDR2 SDRAM
*200-pin DIMM, used for FPM/EDO DRAM in some Sun workstations and servers.
201 to 300 pins
*204-pin SO-DIMM, used for DDR3 SDRAM
*214-pin MicroDIMM, used for DDR2 SDRAM
*240-pin DIMM, used for DDR2 SDRAM, DDR3 SDRAM and FB-DIMM DRAM
*244-pin MiniDIMM, used for DDR2 SDRAM
*260-pin SO-DIMM, used for DDR4 SDRAM
*260-pin SO-DIMM, with different notch position than on DDR4 SO-DIMMs, used for UniDIMMs that can carry either DDR3 or DDR4 SDRAM
*278-pin DIMM, used for HP high density SDRAM.
*288-pin DIMM, used for DDR4 SDRAM and DDR5 SDRAM[1]168-pin SDRAM[edit]Notch positions on DDR (top) and DDR2 (bottom) DIMM modules
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 (order is the same as above).DDR DIMMs[edit]8 GB DDR4-2133 ECC 1.2 V RDIMMs
DDR, DDR2, DDR3, DDR4 and DDR5 all have different pin counts and/or different notch positions. As of August, 2014, DDR4 SDRAM is a modern emerging type of dynamic random access memory (DRAM) with a high-bandwidth (’double data rate’) interface, and has been in use since 2013. It is the higher-speed successor to DDR, DDR2 and DDR3. DDR4 SDRAM is neither forward nor backward compatible with any earlier type of random access memory (RAM) because of different signalling voltages, timings, as well as other differing factors between the technologies and their implementation.SPD EEPROM[edit]
A DIMM’s capacity and other operational parameters may be identified with serial presence detect (SPD), an additional chip which contains information about the module type and timing for the memory controller to be configured correctly. The SPD EEPROM connects to the System Management Bus and may also contain thermal sensors (TS-on-DIMM).[2]Error correction[edit]
ECC DIMMs are those that have extra data bits which can be used by the system memory controller to detect and correct errors. There are numerous ECC schemes, but perhaps the most common is Single Error Correct, Double Error Detect (SECDED) which uses an extra byte per 64-bit word. ECC modules usually carry a multiple of 9 instead of a multiple of 8 chips.Ranking[edit]
Sometimes memory modules are designed with two or more independent sets of DRAM chips connected to the same address and data buses; each such set is called a rank. Ranks that share the same slot, only one rank may be accessed at any given time; it is specified by activating the corresponding rank’s chip select (CS) signal. The other ranks on the module are deactivated for the duration of the operation by having their corresponding CS signals deactivated. DIMMs are currently being commonly manufactured with up to four ranks per module. Consumer DIMM vendors have recently begun to distinguish between single and dual ranked DIMMs.
After a memory word is fetched, the memory is typically inaccessible for an extended period of time while the sense amplifiers are charged for access of the next cell. By interleaving the memory (e.g. cells 0, 4, 8, etc. are stored together in one rank), sequential memory accesses can be performed more rapidly because sense amplifiers have 3 cycles of idle time for recharging, between accesses.
DIMMs are often referred to as ’single-sided’ or ’double-sided’ to describe whether the DRAM chips are located on one or both sides of the module’s printed circuit board (PCB). However, these terms may cause confusion, as the physical layout of the chips does not necessarily relate to how they are logically organized or accessed.
JEDEC decided that the terms ’dual-sided’, ’double-sided’, or ’dual-banked’ were not correct when applied to registered DIMMs (RDIMMs).Organization[edit]
Most DIMMs are built using ’×4’ (’by four’) or ’×8’ (’by eight’) memory chips with nine chips per side; ’×4’ and ’×8’ refer to the data width of the DRAM chips in bits.
In the case of ’×4’ registered DIMMs, the data width per side is 36 bits; therefore, the memory controller (which requires 72 bits) needs to address both sides at the same time to read or write the data it needs. In this case, the two-sided module is single-ranked. For ’×8’ registered DIMMs, each side is 72 bits wide, so the memory controller only addresses one side at a time (the two-sided module is dual-ranked).
The above example applies to ECC memory that stores 72 bits instead of the more common 64. There would also be one extra chip per group of eight, which is not counted.Speeds[edit]
For various technologies, there are certain bus and device clock frequencies that are standardized; there is also a decided nomenclature for each of these speeds for each type.
DIMMs based on Single Data Rate (SDR) DRAM have the same bus frequency for data, address and control lines. DIMMs based on Double Data Rate (DDR) DRAM have data but not the strobe at double the rate of the clock; this is achieved by clocking on both the rising and falling edge of the data strobes. Power consumption and voltage gradually became lower with each generation of DDR-based DIMMs.
Another influence is Column Access Strobe (CAS) latency, or CL which affects memory access speed. This is the delay time between the READ command and the moment data is available. See main article CAS/CL SDR SDRAM DIMMsChipModuleEffective ClockTransfer rateVoltageSDR-66PC-6666 MHz66 MT/s3.3 VSDR-100PC-100100 MHz100 MT/s3.3 VSDR-133PC-133133 MHz133 MT/s3.3 VDDR SDRAM (DDR1) DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR-200PC-1600100 MHz100 MHz200 MT/s2.5 VDDR-266PC-2100133 MHz133 MHz266 MT/s2.5 VDDR-333PC-2700166 MHz166 MHz333 MT/s2.5 VDDR-400PC-3200200 MHz200 MHz400 MT/s2.5 VDDR2 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR2-400PC2-3200200 MHz200 MHz400 MT/s1.8 VDDR2-533PC2-4200266 MHz266 MHz533 MT/s1.8 VDDR2-667PC2-5300333 MHz333 MHz667 MT/s1.8 VDDR2-800PC2-6400400 MHz400 MHz800 MT/s1.8 VDDR2-1066PC2-8500533 MHz533 MHz1066 MT/s1.8 VDDR3 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR3-800PC3-6400400 MHz400 MHz800 MT/s1.5 VDDR3-1066PC3-8500533 MHz533 MHz1066 MT/s1.5 VDDR3-1333PC3-10600667 MHz667 MHz1333 MT/s1.5 VDDR3-1600PC3-12800800 MHz800 MHz1600 MT/s1.5 VDDR3-1866PC3-14900933 MHz933 MHz1866 MT/s1.5 VDDR3-2133PC3-170001066 MHz1066 MHz2133 MT/s1.5 VDDR3-2400PC3-192001200 MHz1200 MHz2400 MT/s1.5 VDDR4 SDRAM DIMMsChipModuleMemory ClockI/O Bus ClockTransfer rateVoltageDDR4-1600PC4-12800800 MHz800 MHz1600 MT/s1.2 VDDR4-1866PC4-14900933 MHz933 MHz1866 MT/s1.2 VDDR4-2133PC4-170001066 MHz1066 MHz2133 MT/s1.2 VDDR4-2400PC4-192001200 MHz1200 MHz2400 MT/s1.2 VDDR4-2666PC4-213001333 MHz1333 MHz2666 MT/s1.2 VDDR4-3200PC4-256001600 MHz1600 MHz3200 MT/s1.2 VForm factors[edit]
Several form factors are commonly used in DIMMs. Single Data Rate Synchronous DRAM (SDR SDRAM) DIMMs were primarily manufactured in 1.5 inches (38 mm) and 1.7 inches (43 mm) heights. When 1U rackmount servers started becoming popular, these form factor registered DIMMs had to plug into angled DIMM sockets to fit in the 1.75 inches (44 mm) high box. To alleviate this issue, the next standards of DDR DIMMs were created with a ’low profile’ (LP) height of around 1.2 inches (30 mm). These fit into vertical DIMM sockets for a 1U platform.
With the advent of blade servers, angled slots have once again become common in order to accommodate LP form factor DIMMs in these space-constrained boxes. This led to the development of the Very Low Profile (VLP) form factor DIMM with a height of around 0.72 inches (18 mm). The DDR3 JEDEC standard for VLP DIMM height is around 0.740 inches (18.8 mm). These will fit vertically in ATCA systems.
Full-height 240-pin DDR2 and DDR3 DIMMs are all specified at a height of around 1.18 inches (30 mm) by standards set by JEDEC. These form factors include 240-pin DIMM, SODIMM, Mini-DIMM and Micro-DIMM.[3]
Full-height 288-pin DDR4 DIMMs are slightly taller than their DDR3 counterparts at 1.23 inches (31 mm). Similarly, VLP DDR4 DIMMs are also marginally taller than their DDR3 equivalent at nearly 0.74 inches (19 mm).[4]
As of Q2 2017, Asus has had a PCI-E based ’DIMM.2’, which has a similar socket to DDR3 DIMMs and is used to put in a module to connect up to two M.2NVMe solid-state drives. However, it cannot use common DDR type ram and does not have much support other than Asus.[5]See also[edit]
*Dual in-line package (DIP)
*Memory geometry – logical configuration of RAM modules (channels, ranks, banks, etc.)
*NVDIMM – non-volatile DIMM
*Rambus in-line memory module (RIMM)
*Single in-line memory module (SIMM)
*Single in-line package (SIP)
*Zig-zag in-line package (ZIP)References[edit]Memory Ram Ddr4
*^Smith, Ryan (2020-07-14). ’DDR5 Memory Specification Released: Setting the Stage for DDR5-6400 And Beyond’. AnandTech. Retrieved 2020-07-15.
*^Temperature Sensor in DIMM memory modules
*^JEDEC MO-269J Whitepaper., accessed Aug. 20, 2014.
*^JEDEC MO-309E Whitepaper., accessed Aug. 20, 2014.
*^ASUS DIMM.2 is a M.2 Riser Card., accessed Jun. 4, 2020.Ddr4 Ram Slot Name PlatesExternal links[edit]Ddr4 Ram Slot Name HoldersWikimedia Commons has media related to DIMM.Ddr4 Memory SpeedRetrieved from ’https://en.wikipedia.org/w/index.php?title=DIMM&oldid=988181755’
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