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Furthermore, it has 120 stream processors, 4 color ROPs, and 8 texture units. The Radeon HD 2600 Pro 512MB AGP incorporates 512 MB of DDR2 memory. Since the memory runs at 400 MHz, and utilizes 128 bit interface, the effective memory bandwidth is 12.8 GB/s. The GPU supports AGP 8x interface, and uses 1 slot on the motherboard. Ddr2 Slot Color online casino bonuses work. There has never been more fierce competition in the gambling industry than now, and casinos constantly have to find new ways to stay competitive and attract new players. Not only do the casinos offer higher Ddr2 Slot Color RTP (return to player) games than Ddr2 Slot Color. Slots in each bank are commonly the same color, so you might see a motherboard with Bank 0 slots (slots 1, 3, and 5) all blue and with Bank 1 slots all black. Triple-channel DIMMs are sold in matched sets of three, similar to how dual-channel DIMMs are sold in matched pairs.
- By Darril Gibson
- 12/15/2012
One type will not fit in the slot of the other without force and possible damage. The key on the dimm slot and the notch on the memory module are in different locations on DDR2 and DDR3. To illustrate, here's an image of DDR2 slots. The orange and yellow slots are reversed, notice the difference in the locations of the key, they're fairly. So, what kind of ram did you buy? Crucial says your board as 4 slots that will hold 1 gig in each slot for a total of 4 gigs. I would remove the two older sticks and install a 1 gig stick in each slot that is of the same color. Usually slots 1 and 3. You might be looking at a new Power supply too.
- RAM
Exam 220-801 objectives in this chapter:
1.2 Differentiate between motherboard components, their purposes, and properties.
CPU sockets
1.3 Compare and contrast RAM types and features.
Types
DDR
DDR2
DDR3
SDRAM
SODIMM
RAMBUS
DIMM
Parity vs. non-parity
ECC vs. non-ECC
RAM configurations
Single channel vs. dual channel vs. triple channel
Single sided vs. double sided
RAM compatibility and speed
1.6 Differentiate among various CPU types and features and select the appropriate cooling method.
Socket types
Intel: LGA, 775, 1155, 1156, 1366
AMD: 940, AM2, AM2+, AM3, AM3+, FM1, F
Characteristics
Speeds
Cores
Cache size/type
Hyperthreading
Virtualization support
Architecture (32-bit vs. 64-bit)
Integrated GPU
Cooling
Heat sink
Fans
Thermal paste
Liquid-based
Exam 220-802 objectives in this chapter:
4.2 Given a scenario, troubleshoot common problems related to motherboards, RAM, CPU and power with appropriate tools.
Common symptoms
Unexpected shutdowns
System lockups
Overheating
RAM
When technicians are talking about a computer’s memory, they are primarily talking about random access memory (RAM). RAM is used for short-term storage of applications or data so that the processor can access and use this information. In contrast, computers use hard drives for long-term storage of data.
Most RAM is volatile. This doesn’t mean that it’s explosive; it means that data in RAM is lost when power is removed.
As an introduction, the following list identifies commonly used types of RAM. All of these types of RAM are volatile.
Dynamic RAM (DRAM). Dynamic refers to how bits are stored in an electrical component called a capacitor. The capacitor holds the bit as a charge, but the capacitor needs to be regularly refreshed to hold the charge. This configuration uses very few components per bit, keeping the cost low, but the constant refresh reduces the speed.
Synchronous DRAM (SDRAM). SDRAM is synchronized with a clock for faster speeds. Almost all primary DRAM used in computers today is SDRAM, but it’s often listed as DRAM to avoid confusion with SRAM.
Static RAM (SRAM). Static RAM uses switching circuitry instead of capacitors and can hold a charge without a constant refresh. It requires more components per bit so it is more expensive, but due to how the switching works, it is quicker than DRAM. Due to the speed, SRAM is commonly used for CPU cache (described later in this chapter) but is rarely used as the primary RAM because of its cost.
Flash memory is very popular, but not as the primary RAM used in a system. USB flash drives, solid-state drives (SSDs), and memory cards used in cameras and other mobile devices all use flash memory. Flash memory is used for BIOS in many motherboards. Unlike DRAM and SRAM, flash memory is not volatile and retains data without power.
Double Data Rate SDRAM
While the original SDRAM versions were quick and efficient for their time, manufacturers have steadily improved them. Double data rate (DDR) is one of the improvements and is used in almost all SDRAM. As a reminder, SDRAM is tied to a clock, and when the clock ticks, data is transferred.
SDRAM uses only the leading edge for the clock. However, each of the DDR SDRAM versions uses both the leading and trailing edge of the clock. This is often called double pumping. Figure 3-1 compares the two over two cycles of a clock. You can see that SDRAM has two clocks from these cycles and that DDR has four clocks from the same two cycles.
Figure 3-1. SDRAM compared with double-pumping DDR.
The following list provides an overview of the different DDR versions:
Double Data Rate (DDR) SDRAM. DDR uses double pumping to double the data rate of SDRAM.
DDR2. DDR2 doubles the data rate of DDR. In addition to double pumping, it modifies the way that data is processed and can transfer twice as much data as DDR SDRAM.
DDR3. DDR3 doubles the data rate of DDR2. It uses double pumping and further modifies the way that data is processed. It can transfer four times as much data as DDR and eight times as much data as SDRAM.
DDR4 isn’t included in the objectives, but it is on the horizon as a replacement for DDR3. It’s expected to double the speed of DDR3.
DIMMs and SODIMMs
RAM comes on cards plugged into the slots in the motherboard. They are smaller than expansion cards, and technicians commonly call memory cards sticks. The two most common types of memory sticks are:
Dual in-line memory module (DIMM). A DIMM is the circuit board that holds the memory chips.
Small outline dual in-line memory module (SODIMM). SODIMM chips are smaller and are used in smaller devices such as laptop computers and some printers.
Figure 3-2 shows a DIMM (top) and a SODIMM (bottom).
DIMMs and SODIMMs have a different number of pins depending on the type used.
DDR SDRAM DIMM: 184 pins
DDR2 SDRAM DIMM: 240 pins
DDR3 SDRAM DIMM: 240 pins
DDR SDRAM SODIMM: 200 pins
DDR2 SDRAM SODIMM: 144 or 200 pins
DDR3 SDRAM SODIMM: 204 pins
Single Channel, Dual Channel, and Triple Channel
Many motherboards and CPUs support single-channel, dual-channel, and triple-channel memory architectures. Each single channel represents a separate 64-bit line of communication that can be accessed independently. With dual channel, the system can access 128 bits at a time; triple channel gives it access to 192 bits at a time.
Using dual and triple channels provides an additional performance enhancement to DDR, DDR2, and DDR3, in addition to double pumping and other enhancements provided by the DDR versions. If you use a dual-channel motherboard with DDR3, it doubles the throughput of DDR3, providing 16 times more data throughput than SDRAM.
If you are upgrading a computer’s memory, it’s important to understand these channels. You can purchase DIMMs in matched pairs. Where you install each DIMM determines how many channels your system will use and can affect the performance of RAM.
Single Channel vs. Dual Channel
Dual-channel motherboards are very common. If you look at a dual-channel motherboard, you see that it has four memory slots, two slots of one color and two slots of another color. Figure 3-3 shows a diagram of four memory slots labeled for a motherboard using an Intel-based CPU. Slots 1 and 3 are one color, and slots 2 and 4 are another color.
Figure 3-3. Intel-based DDR slots (S), banks (B), and channels (C).
Slots: Each slot can accept one DIMM.
Banks: A bank is composed of two slots. In Figure 3-3, Bank 0 includes slots 1 and 3 and these two slots are normally blue. Bank 1 includes slots 2 and 4 and these slots are normally black. This is standard for Intel CPU-based motherboards.
Channels: Each channel represents a separate 64-bit communication path. Slots 1 and 2 make up one channel, and slots 3 and 4 make up the second channel.
You can install a single DIMM in slot 1, and the system will have a single-channel RAM. You can purchase DIMMs in matched pairs, and it’s important to know in which slots to install them. For the best performance, you should install matched DIMMs in the same bank. Looking at Figure 3-3, you should install the matched pair of DIMMs in slots 1 and 3 (Bank 0), leaving slots 2 and 4 empty. The system will take advantage of the dual-channel architecture by using two separate 64-bit channels.
What happens if you install the DIMMs in slots 1 and 2 instead? The system will still work; however, both DIMMs are installed in channel 1, so the system will work with only a single channel. RAM will be about half as fast as it could be if it were installed correctly to take advantage of the dual channels.
Figure 3-3 and the previous explanation describe the color coding, banks, and channels for Intel-based CPU motherboards. However, most motherboards designed for AMD CPUs are organized differently, as shown in Figure 3-4. On these motherboards, slots 1 and 2 make up Bank 0, and slots 3 and 4 make up Bank 1. Channel 1 includes slots 1 and 3, and channel 2 includes slots 2 and 4.
Figure 3-4. AMD-based DDR slots (S), banks (B), and channels (C).
While this can be confusing between different motherboards, the good news is that most motherboard manufacturers use the same color for each bank. For Intel-based motherboards, Bank 0 includes slots 1 and 3, and these will be the same color (often blue). Bank 1 includes slots 2 and 4, and they will be a different color (often black). AMD motherboards also use one color for Bank 0 (slots 1 and 2) and another color for Bank 1 (slots 3 and 4).
Triple Channel
On some motherboards, you see six DIMM slots instead of four. This indicates the system supports triple-channel memory usage. Table 3-1 shows the configuration of the slots, banks, and channels for a motherboard using triple-channel RAM.
Table 3-1. Triple-Channel DIMMs
Slots | Banks | Channels |
Slot 1 | Bank 0 | Channel 1 |
Slot 2 | Bank 1 | Channel 1 |
Slot 3 | Bank 0 | Channel 2 |
Slot 4 | Bank 1 | Channel 2 |
Slot 5 | Bank 0 | Channel 3 |
Slot 6 | Bank 1 | Channel 3 |
Slots in each bank are commonly the same color, so you might see a motherboard with Bank 0 slots (slots 1, 3, and 5) all blue and with Bank 1 slots all black.
Triple-channel DIMMs are sold in matched sets of three, similar to how dual-channel DIMMs are sold in matched pairs. When you install triple-channel DIMMs, you should install the matched set in the same bank. For example, if you bought one set, you’d install it in slots 1, 3, and 5.
Single Sided vs. Double Sided
You’d think that single-sided and double-sided RAM refers to how many sides of a DIMM have chips. That makes sense, but it’s not entirely accurate. Instead, single sided or double sided refers to how a system can access the RAM.
In double-sided RAM, the RAM is separated into two groups known as ranks, and the system can access only one rank at a time. If it needs to access the other rank, it needs to switch to the other rank. In contrast, single-sided (or single-rank) RAM is in a single group; the system can access all RAM on the DIMM without switching.
If you have a DIMM with chips on only one side, it is most likely a single-sided (single-rank) DIMM. However, if it has chips on both sides, it can be single rank, dual rank, or even quad rank. You often have to dig into the specs to determine how many ranks it is using.
Usually, you’d think that double is better than single, but in this case, more rank is not better. Switching back and forth between ranks takes time and slows down the RAM. Single-sided RAM doesn’t switch, and if all other factors are the same, single-sided RAM is faster than double-sided RAM.
RAM Compatibility and Speed
An important point about DDR, DDR2, and DDR3 is that they aren’t compatible with each other. You can’t use any version in a slot designed for another type. For example, you can use DDR3 DIMMs only in DDR3 slots. From a usability perspective, that’s not so great, but if you’re trying to remember which types are compatible, it’s a lot easier. You can’t mix and match them.
Figure 3-5 shows a comparison of the keyings of DDR, DDR2, and DDR3, with a dotted line as a reference through the middle of each one. You can see that the notched key at the bottom of the circuit card is different for each. The standards aren’t compatible, and this keying prevents technicians from inserting a DIMM into the wrong slot.
Speeds
Some RAM is faster than other RAM, and with faster RAM you often see faster overall performance. As you’d expect, faster RAM is more expensive. If you’re shopping for RAM, you want to ensure that you buy exactly what you need. This includes the correct DDR version, the correct number of channels if your motherboard supports multiple channels, and the correct speed.
The speed of RAM is expressed as the number of bytes it can transfer in a second (B/s) or, more commonly, as megabytes per second (MB/s). However, the speed of most RAM isn’t listed plainly. Instead, it’s listed using standard names and module names such as DDR3-800 or PC3-12800, respectively. These names indicate their speed, but not directly. If you need to shop for RAM, you need to understand these names and how they relate to the speed.
You can calculate the overall speed of any SDRAM DDR type by using a specific mathematical formula for that type. The formula includes the speed of the clock (Clk), a clock multiplier (Clk Mult) for DDR2 and DDR3, and doubling from double pumping (DP). The speed is calculated for a single channel, which is 64 bits wide, and then converted to bytes by dividing it by 8. The following formulas show how to calculate the speed of each of the DDR versions by using a 100-MHz clock:
DDR speed calculation:
Clk x 2 (DP) x 64 (bits) / 8 (bytes)
100 MHz x 2 x 64 / 8 = 1,600 MB/s
DDR2 speed calculation:
Clk x 2 (Clk Mult) x 2 (DP) x 64 (bits) / 8 (bytes)
100 MHz x 2 x 2 x 64 / 8 = 3,200 MB/s
DDR3 speed calculation:
Clk x 4 (Clk Mult) x 2 (DP) x 64 (bits) / 8 (bytes)
100 MHz x 4 x 2 x 64 / 8 = 6,400 MB/s
Table 3-2 shows how these speeds relate to the different naming conventions used with DDR types. You can see that the standard name is derived from the clock, the clock multiplier, and double pumping. For example, DDR3 uses a 4-times multiplier and double pumping. Therefore, it’s eight times faster than SDRAM. The standard name is derived by multiplying the clock by 8. The module name is a little more cryptic, but if you calculate the speed by using the clock, you can see that the PC name indicates the calculated speed in MB/s. Also, you can see that the names include the version (DDR, DDR2, or DDR3).
Table 3-2. DDR Standard Names and Module Names
100 MHz | 166 2/3 MHz | 200 MHz | |
DDR Standard Name DDR Module Name | DDR-200 PC-1600 | DDR-333 PC-2700 | DDR-400 PC-3200 |
DDR2 Standard Name DDR2 Module Name | DDR2-400 PC2-3200 | DDR2-667 PC2-5300 PC2-5400 | DDR2-800 PC2-6400 |
DDR3 Standard Name DDR3 Module Name | DDR3-800 PC3-6400 | DDR3-1333 PC3-10600 | DDR3-1600 PC3-12800 |
Each DDR version supports multiple clock speeds, and each newer version supports faster clocks. Some of the clock speeds supported by different DDR versions are as follows:
DDR: 100, 133 1/3, 166 2/3, and 200 MHz
DDR2: 100, 133 1/3, 166 2/3, 200, and 266 2/3 MHz
DDR3: 100, 133 1/3, 166 2/3, 200, 266 2/3, and 400 MHz
A key consideration when purchasing RAM is to ensure that the RAM speeds are supported by the motherboard. If the speeds don’t match, the motherboard defaults to the slower speed. For example, if your motherboard has a 100-MHz clock and you install PC3-12800 RAM, the RAM will run at 100 MHz instead of 200 MHz. It still works, but you won’t get the benefit of the higher-speed RAM.
Compatibility within Banks
In addition to matching the RAM speed with the motherboard speed, you should also match the RAM speed within banks when using dual-channel and triple-channel configurations. If one DIMM in a bank fails, you should replace both with a matched set. However, if you have to replace the failed DIMM with a spare, look for a spare that uses the same speed.
For example, if Bank 0 currently has two PC3-12800 sticks and one fails, you should replace the failed stick with a PC3-12800 stick. PC3-12800 uses a 200-MHz clock. If you replaced it with a PC3-6400 (designed for a 100-MHz clock), both sticks would run at the slower speed or revert to single channel.
Shopping for RAM
When shopping for RAM, you need to determine the clock speed of your computer and then determine the DDR name. You can boot into BIOS, as shown in Chapter 2, “Understanding Motherboards and BIOS,” to identify the clock speed used by RAM and then plug it into the formula to determine the standard name and module name.
If you have access to the Internet, there’s an easier way. You can go to one of the memory sites, such as Crucial.com or Kingston.com, and use one of their tools. You can enter the make and model of your computer, and the tool will tell you what memory is supported. Crucial.com also has an application that you can download and run to identify your motherboard, the type and speeds of supported RAM, how much RAM is installed, and recommendations for upgrading the RAM. Another tool that can help is CPU-Z (described at the end of this chapter).
Parity and ECC
Desktop systems rarely need extra hardware to detect or correct memory errors, but some advanced servers need this ability. The two primary error-detection technologies are parity and error correction code (ECC). When shopping for RAM on desktop systems, you’ll almost always buy non-parity and non-ECC RAM.
Parity works by using 9 bits for every byte instead of 8 bits. It sets the ninth bit to a 0 or a 1 for each byte when writing data to RAM. Parity can be odd parity or even parity, referring to odd and even numbers.
Odd parity is common, and when used, it ensures that the 9 bits always have an odd number of 1s. For example, if the 8 data bits were 1010 1010, it has four 1s. Four is an even number, so the parity bit needs to be a 1. Whenever data is written to RAM, the parity bit is calculated and written with each byte.
When the data is read, the system calculates the parity from the 9 bits. If it ever detects an even number of 1s, it knows there is an error, meaning that the data isn’t valid and should not be used. Parity can’t fix the problem; it just reports the error.
ECC RAM uses additional circuitry and can detect and correct errors. This extra circuitry adds significantly to the cost of the RAM and should be purchased only when necessary. For example, spacecraft that might be exposed to solar flares commonly use ECC RAM. Additionally, some high-end scientific and financial servers need it to ensure that the data in RAM remains error-free.
Rambus and RDRAM
Another type of DRAM is Rambus DRAM (RDDRAM). More commonly, you see it referred to as Rambus, Rambus DRAM, or RDRAM. RDRAM is not compatible with any of the DDR versions and is rarely used.
The circuit boards are called Rambus in-line memory modules (RIMMs) instead of DIMMs. When installing RDRAM, you must install it in pairs. In some cases, only one circuit card has memory and the second circuit card in the pair is needed to complete the circuit. The second card is called a continuity RIMM (CRIMM).
RDRAM generates quite a bit of heat. To dissipate the heat, the chips are covered with a piece of metal acting as a heat sink or heat spreader. This makes them easy to identify because DDR SDRAM is not covered with metal.
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Related resources
| Type of RAM | |
Front and back of a 2GB PC2-5300 DDR2 RAM module for desktop PCs (DIMM) | |
| Developer | Samsung[1] JEDEC |
|---|---|
| Type | Synchronous dynamic random-access memory |
| Generation | 2nd generation |
| Release date | 2003 |
| Standards |
|
| Clock rate | 100–266 MHz |
| Cycle time | 10–3.75 ns |
| Bus clock rate | 200–533 MHz |
| Transfer rate | 400–1066 MT/s |
| Voltage | 1.8 V |
| Predecessor | DDR SDRAM |
| Successor | DDR3 SDRAM |
Double Data Rate 2 Synchronous Dynamic Random-Access Memory, officially abbreviated as DDR2 SDRAM, is a double data rate (DDR) synchronous dynamic random-access memory (SDRAM) interface. It superseded the original DDR SDRAM specification, and was itself superseded by DDR3 SDRAM (launched in 2007). DDR2 DIMMs are neither forward compatible with DDR3 nor backward compatible with DDR.
In addition to double pumping the data bus as in DDR SDRAM (transferring data on the rising and falling edges of the bus clock signal), DDR2 allows higher bus speed and requires lower power by running the internal clock at half the speed of the data bus. The two factors combine to produce a total of four data transfers per internal clock cycle.
Since the DDR2 internal clock runs at half the DDR external clock rate, DDR2 memory operating at the same external data bus clock rate as DDR results in DDR2 being able to provide the same bandwidth but with better latency. Alternatively, DDR2 memory operating at twice the external data bus clock rate as DDR may provide twice the bandwidth with the same latency. The best-rated DDR2 memory modules are at least twice as fast as the best-rated DDR memory modules.The maximum capacity on commercially available DDR2 DIMMs is 8GB, but chipset support and availability for those DIMMs is sparse and more common 2GB per DIMM are used.[citation needed][2]
History[edit]
DDR2 SDRAM was first produced by Samsung in 2001. In 2003, the JEDEC standards organization presented Samsung with its Technical Recognition Award for the company's efforts in developing and standardizing DDR2.[1]
DDR2 was officially introduced in the second quarter of 2003 at two initial clock rates: 200 MHz (referred to as PC2-3200) and 266 MHz (PC2-4200). Both performed worse than the original DDR specification due to higher latency, which made total access times longer. However, the original DDR technology tops out at a clock rate around 200 MHz (400 MT/s). Higher performance DDR chips exist, but JEDEC has stated that they will not be standardized. These chips are mostly standard DDR chips that have been tested and rated to be capable of operation at higher clock rates by the manufacturer. Such chips draw significantly more power than slower-clocked chips, but usually offered little or no improvement in real-world performance. DDR2 started to become competitive against the older DDR standard by the end of 2004, as modules with lower latencies became available.[3]
Specification[edit]
Overview[edit]
The key difference between DDR2 and DDR SDRAM is the increase in prefetch length. In DDR SDRAM, the prefetch length was two bits for every bit in a word; whereas it is four bits in DDR2 SDRAM. During an access, four bits were read or written to or from a four-bit-deep prefetch queue. This queue received or transmitted its data over the data bus in two data bus clock cycles (each clock cycle transferred two bits of data). Increasing the prefetch length allowed DDR2 SDRAM to double the rate at which data could be transferred over the data bus without a corresponding doubling in the rate at which the DRAM array could be accessed. DDR2 SDRAM was designed with such a scheme to avoid an excessive increase in power consumption.
DDR2's bus frequency is boosted by electrical interface improvements, on-die termination, prefetch buffers and off-chip drivers. However, latency is greatly increased as a trade-off. The DDR2 prefetch buffer is four bits deep, whereas it is two bits deep for DDR. While DDR SDRAM has typical read latencies of between two and three bus cycles, DDR2 may have read latencies between three and nine cycles, although the typical range is between four and six. Thus, DDR2 memory must be operated at twice the data rate to achieve the same latency.
Another cost of the increased bandwidth is the requirement that the chips are packaged in a more expensive and difficult to assemble BGA package as compared to the TSSOP package of the previous memory generations such as DDR SDRAM and SDR SDRAM. This packaging change was necessary to maintain signal integrity at higher bus speeds.
Power savings are achieved primarily due to an improved manufacturing process through die shrinkage, resulting in a drop in operating voltage (1.8 V compared to DDR's 2.5 V). The lower memory clock frequency may also enable power reductions in applications that do not require the highest available data rates.
According to JEDEC[4] the maximum recommended voltage is 1.9 volts and should be considered the absolute maximum when memory stability is an issue (such as in servers or other mission critical devices). In addition, JEDEC states that memory modules must withstand up to 2.3 volts before incurring permanent damage (although they may not actually function correctly at that level).
Chips and modules[edit]
For use in computers, DDR2 SDRAM is supplied in DIMMs with 240 pins and a single locating notch. Laptop DDR2 SO-DIMMs have 200 pins and often come identified by an additional S in their designation. DIMMs are identified by their peak transfer capacity (often called bandwidth).
| Name | Chip | Bus | Timings | ||||||
|---|---|---|---|---|---|---|---|---|---|
| Standard | Type | Module | Clock rate(MHz) | Cycle time (ns)[5] | Clock rate (MHz) | Transfer rate(MT/s) | Bandwidth(MB/s) | CL-TRCD-TRP[6][7] | CAS latency(ns) |
| DDR2-400 | B | PC2-3200 | 100 | 10 | 200 | 400 | 3200 | 3-3-3 | 15 |
| C | 4-4-4 | 20 | |||||||
| DDR2-533 | B | PC2-4200* | 133 | 7.5 | 266 | 533 | 4266 | 3-3-3 | 11.25 |
| C | 4-4-4 | 15 | |||||||
| DDR2-667 | C | PC2-5300* | 166 | 6 | 333 | 667 | 5333 | 4-4-4 | 12 |
| D | 5-5-5 | 15 | |||||||
| DDR2-800 | C | PC2-6400 | 200 | 5 | 400 | 800 | 6400 | 4-4-4 | 10 |
| D | 5-5-5 | 12.5 | |||||||
| E | 6-6-6 | 15 | |||||||
| DDR2-1066 | E | PC2-8500* | 266 | 3.75 | 533 | 1066 | 8533 | 6-6-6 | 11.25 |
| F | 7-7-7 | 13.125 | |||||||
| PC-5300 | PC-6400 | ||||
|---|---|---|---|---|---|
| 5-5-5 | 4-4-4 | 6-6-6 | 5-5-5 | 4-4-4 | |
| PC2-3200 4-4-4 | % | % | +33% | +60% | % |
| PC2-3200 3-3-3 | % | % | = | +20% | % |
| PC2-4200 4-4-4 | % | % | = | +21% | % |
| PC2-4200 3-3-3 | % | % | −24% | −9% | % |
| PC2-5300 5-5-5 | % | % | = | +21% | % |
| PC2-5300 4-4-4 | % | % | −19% | −3% | % |
| PC2-6400 6-6-6 | % | % | = | +20% | % |
| PC2-6400 5-5-5 | % | % | −16% | = | % |
| PC2-6400 4-4-4 | % | % | −33% | −20% | % |
| PC2-8500 7-7-7 | % | % | −12% | +6% | % |
| PC2-8500 6-6-6 | % | % | −25% | −9% | % |
* Some manufacturers label their DDR2 modules as PC2-4300, PC2-5400 or PC2-8600 instead of the respective names suggested by JEDEC. At least one manufacturer has reported this reflects successful testing at a higher-than-standard data rate[8] whilst others simply round up for the name.
Note: DDR2-xxx denotes data transfer rate, and describes raw DDR chips, whereas PC2-xxxx denotes theoretical bandwidth (with the last two digits truncated), and is used to describe assembled DIMMs. Bandwidth is calculated by taking transfers per second and multiplying by eight. This is because DDR2 memory modules transfer data on a bus that is 64 data bits wide, and since a byte comprises 8 bits, this equates to 8 bytes of data per transfer.
In addition to bandwidth and capacity variants, modules can:
- Optionally implement ECC, which is an extra data byte lane used for correcting minor errors and detecting major errors for better reliability. Modules with ECC are identified by an additional ECC in their designation. PC2-4200 ECC is a PC2-4200 module with ECC. An additional P can be added at the end of the designation, P standing for parity (ex : PC2-5300P).
- Intel ® 6402 Advanced Memory BufferBe 'registered' ('buffered'), which improves signal integrity (and hence potentially clock rates and physical slot capacity) by electrically buffering the signals at a cost of an extra clock of increased latency. Those modules are identified by an additional R in their designation, whereas non-registered (a.k.a. 'unbuffered') RAM may be identified by an additional U in the designation. PC2-4200R is a registered PC2-4200 module, PC2-4200R ECC is the same module but with additional ECC.
- Be aware fully buffered modules, which are designated by F or FB do not have the same notch position as other classes. Fully buffered modules cannot be used with motherboards that are made for registered modules, and the different notch position physically prevents their insertion.
Note:
- Registered and un-buffered SDRAM generally cannot be mixed on the same channel.
- The highest-rated DDR2 modules in 2009 operate at 533 MHz (1066 MT/s), compared to the highest-rated DDR modules operating at 200 MHz (400 MT/s). At the same time, the CAS latency of 11.2 ns = 6 / (bus clock rate) for the best PC2-8500 modules is comparable to that of 10 ns = 4 / (bus clock rate) for the best PC-3200 modules.
Backward compatibility[edit]
DDR2 DIMMs are not backward compatible with DDR DIMMs. The notch on DDR2 DIMMs is in a different position from DDR DIMMs, and the pin density is higher than DDR DIMMs in desktops. DDR2 is a 240-pin module, DDR is a 184-pin module. Notebooks have 200-pin SO-DIMMs for DDR and DDR2; however, the notch on DDR2 modules is in a slightly different position than on DDR modules.
Higher-speed DDR2 DIMMs can be mixed with lower-speed DDR2 DIMMs, although the memory controller will operate all DIMMs at same speed as the lowest-speed DIMM present.
Relation to GDDR memory[edit]
GDDR2, a form of GDDR SDRAM, was developed by Samsung and introduced in July 2002.[9] The first commercial product to claim using the 'DDR2' technology was the NvidiaGeForce FX 5800 graphics card. However, it is important to note that this GDDR2 memory used on graphics cards is not DDR2 per se, but rather an early midpoint between DDR and DDR2 technologies. Using 'DDR2' to refer to GDDR2 is a colloquialmisnomer. In particular, the performance-enhancing doubling of the I/O clock rate is missing. It had severe overheating issues due to the nominal DDR voltages. ATI has since designed the GDDR technology further into GDDR3, which is based on DDR2 SDRAM, though with several additions suited for graphics cards.
GDDR3 and GDDR5 is now commonly used in modern graphics cards and some tablet PCs. However, further confusion has been added to the mix with the appearance of budget and mid-range graphics cards which claim to use 'GDDR2'. These cards actually use standard DDR2 chips designed for use as main system memory although operating with higher latencies to achieve higher clockrates. These chips cannot achieve the clock rates of GDDR3 but are inexpensive and fast enough to be used as memory on mid-range cards.
See also[edit]
- CAS latency (definition of 'CAS 5-5-5-15', for example)
References[edit]
- ^ ab'Samsung Demonstrates World's First DDR 3 Memory Prototype'. Phys.org. 17 February 2005. Retrieved 23 June 2019.
- ^https://media-www.micron.com/-/media/client/global/documents/products/data-sheet/modules/parity_rdimm/htf36c256_512_1gx72pz.pdf?rev=e8e3928f09794d61809f92abf36bfb24
- ^Ilya Gavrichenkov. 'DDR2 vs. DDR: Revenge gained'. X-bit Laboratories. Archived from the original on 2006-11-21.
- ^JEDEC JESD 208 (section 5, tables 15 and 16)
- ^Cycle time is the inverse of the I/O bus clock frequency; e.g., 1/(100 MHz) = 10 ns per clock cycle.
- ^'DDR2 SDRAM SPECIFICATION'(PDF). JESD79-2E. JEDEC. April 2008: 78. Retrieved 2009-03-14.Cite journal requires
journal=(help) - ^'SPECIALITY DDR2-1066 SDRAM'(PDF). JEDEC. November 2007: 70. Retrieved 2009-03-14.Cite journal requires
journal=(help) - ^Mushkin PC2-5300 vs. Corsair PC2-5400
- ^'Samsung Electronics Announces JEDEC-Compliant 256Mb GDDR2 for 3D Graphics'. Samsung Electronics. Samsung. 23 August 2003. Retrieved 26 June 2019.
Further reading[edit]
- JEDEC standard: DDR2 SDRAM Specification: JESD79-2F, November 2009 ** http://www.jedec.org/standards-documents/docs/jesd-79-2e
- JEDEC standard: DDR2-1066 **
- 'JEDEC Standard No. 21C: 4.20.13 240-Pin PC2-5300/PC2-6400 DDR2 SDRAM Unbuffered DIMM Design Specification' **
- JEDEC Solid State Technology Association
- Razak Mohammed Ali. 'DDR2 SDRAM interfaces for next-gen systems'(PDF). Electronic Engineering Times. Archived from the original(PDF) on 2007-09-26.
Note**: JEDEC website requires registration ($2,500 membership) for viewing or downloading of these documents: http://www.jedec.org/standards-documents