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SIMMs, DIMMs, and RIMMs

Originally, PCs had memory installed via individual chips. They are often referred to as dual inline package (DIP) chips because of their physical designs. The original IBM XT and AT systems had 36 sockets on the motherboard for these individual chips—and more sockets could often be found on memory cards plugged into the bus slots. I remember spending hours populating boards with these chips, which was a tedious job.

Besides being a time-consuming and labor-intensive way to deal with memory, DIP chips had one notorious problem—they crept out of their sockets over time as the system went through thermal cycles. Every day, when you powered the system on and off, the system heated and cooled, and the chips gradually walked their way out of the sockets—a phenomenon called chip creep. Eventually, good contact was lost and memory errors resulted. Fortunately, reseating all the chips back in their sockets usually rectified the problem, but that method was labor intensive if you had a lot of systems to support.

The alternative to this at the time was to have the memory soldered into either the motherboard or an expansion card. This prevented the chips from creeping and made the connections more permanent, but it caused another problem. If a chip did go bad, you had to attempt desoldering the old one and resoldering a new one or resort to scrapping the motherboard or memory card on which the chip was installed. This was expensive and made memory troubleshooting difficult.

A chip was needed that was both soldered and removable, which was made possible by using memory modules instead of individual chips. Early modules had one row of electrical contacts and were called SIMMs (single inline memory modules), whereas later modules had two rows and were called DIMMs (dual inline memory modules) or RIMMs (Rambus inline memory modules). These small boards plug into special connectors on a motherboard or memory card. The individual memory chips are soldered to the module, so removing and replacing them is impossible. Instead, you must replace the entire module if any part of it fails. The module is treated as though it were one large memory chip.

Several different types of SIMMs, DIMMs, and RIMMs have been commonly used in desktop systems. The various types are often described by their pin count, memory row width, or memory type.

SIMMs, for example, are available in two main physical types—30-pin (8 bits plus an option for 1 additional parity bit) and 72-pin (32 bits plus an option for 4 additional parity bits)—with various capacities and other specifications. The 30-pin SIMMs are physically smaller than the 72-pin versions, and either version can have chips on one or both sides. SIMMs were widely used from the late 1980s to the late 1990s but have become obsolete.

DIMMs are available in four main types. SDR (single data rate) DIMMs have 168 pins, one notch on either side, and two notches along the contact area. DDR (double data rate) DIMMs, on the other hand, have 184 pins, two notches on each side, and only one offset notch along the contact area. DDR2 and DDR3 DIMMs have 240 pins, two notches on each side, and one near the center of the contact area. All DIMMs are either 64 bits (non-ECC/parity) or 72 bits (data plus parity or error-correcting code [ECC]) wide. The main physical difference between SIMMs and DIMMs is that DIMMs have different signal pins on each side of the module, resulting in two rows of electrical contacts. That is why they are called dual inline memory modules, and why with only 1" of additional length, they have many more pins than a SIMM.

RIMMs also have different signal pins on each side. Three different physical types of RIMMs are available: a 16/18-bit version with 184 pins, a 32/36-bit version with 232 pins, and a 64/72-bit version with 326 pins. Each of these plugs into the same sized connector, but the notches in the connectors and RIMMs are different to prevent a mismatch. A given board will accept only one type. By far the most common type is the 16/18-bit version. The 32-bit version was introduced in late 2002, and the 64-bit version was introduced in 2004.

The standard 16/18-bit RIMM has 184 pins, one notch on either side, and two notches centrally located in the contact area. The 16-bit versions are used for non-ECC applications, whereas the 18-bit versions incorporate the additional bits necessary for ECC.

Figures 6.3 through 6.9 show a typical 30-pin (8-bit) SIMM, 72-pin (32-bit) SIMM, 168-pin SDRAM DIMM, 184-pin DDR SDRAM (64-bit) DIMM, 240-pin DDR2 DIMM, 240-pin DDR3 DIMM, and 184-pin RIMM, respectively. The pins are numbered from left to right and are connected through to both sides of the module on the SIMMs. The pins on the DIMM are different on each side, but on a SIMM, each side is the same as the other and the connections carry through. Note that all dimensions are in both inches and millimeters (in parentheses), and modules are generally available in error-correcting code (ECC) versions with 1 extra ECC (or parity) bit for every 8 data bits (multiples of 9 in data width) or versions that do not include ECC support (multiples of 8 in data width).

Figure 6.3

Figure 6.3 A typical 30-pin SIMM.

Figure 6.4

Figure 6.4 A typical 72-pin SIMM.

Figure 6.5

Figure 6.5 A typical 168-pin SDRAM DIMM.

Figure 6.6

Figure 6.6 A typical 184-pin DDR DIMM.

Figure 6.7

Figure 6.7 A typical 240-pin DDR2 DIMM.

Figure 6.8

Figure 6.8 A typical 240-pin DDR3 DIMM.

Figure 6.9

Figure 6.9 A typical 184-pin RIMM.

All these memory modules are fairly compact considering the amount of memory they hold and are available in several capacities and speeds. Table 6.13 lists the various capacities available for SIMMs, DIMMs, and RIMMs.

Table 6.13. SIMM, DIMM, and RIMM Capacities

Capacity

Standard DepthxWidth

Parity/ECC DepthxWidth

30-Pin SIMM

256KB

256Kx8

256Kx9

1MB

1Mx8

1Mx9

4MB

4Mx8

4Mx9

16MB

16Mx8

16Mx9

72-Pin SIMM

1MB

256Kx32

256Kx36

2MB

512Kx32

512Kx36

4MB

1Mx32

1Mx36

8MB

2Mx32

2Mx36

16MB

4Mx32

4Mx36

32MB

8Mx32

8Mx36

64MB

16Mx32

16Mx36

128MB

32Mx32

32Mx36

168/184-Pin DIMM/DDR DIMM

8MB

1Mx64

1Mx72

16MB

2Mx64

2Mx72

32MB

4Mx64

4Mx72

64MB

8Mx64

8Mx72

128MB

16Mx64

16Mx72

256MB

32Mx64

32Mx72

512MB

64Mx64

64Mx72

1,024MB

128Mx64

128Mx72

2,048MB

256Mx64

256Mx72

240-Pin DDR2/DDR3 DIMM

256MB

32Mx64

32Mx72

512MB

64Mx64

64Mx72

1,024MB

128Mx64

128Mx72

2,048MB

256Mx64

256Mx72

4,096MB

512Mx64

512Mx72

184-Pin RIMM

64MB

32Mx16

32Mx18

128MB

64Mx16

64Mx18

256MB

128Mx16

128Mx18

512MB

256Mx16

256Mx18

1,024MB

512Mx16

512Mx18

Memory modules of each type and capacity are available in various speed ratings. Consult your motherboard documentation for the correct memory speed and type for your system. If a system requires a specific speed memory module, you can almost always substitute faster speeds if the one specified is not available. Generally, no problems occur in mixing module speeds, as long as you use modules equal to or faster than what the system requires. Because there's little price difference between the various speed versions, I often buy faster modules than are necessary for a particular application, especially if they are the same cost as slower modules. This might make them more usable in a future system that could require the faster speed.

Because SDRAM and newer modules have an onboard serial presence detect (SPD) ROM that reports their speed and timing parameters to the system, most systems run the memory controller and memory bus at the speed matching the slowest module installed.

You can't always replace a module with a higher-capacity unit and expect it to work. Systems might have specific design limitations for the maximum capacity of module they can take. A larger-capacity module works only if the motherboard is designed to accept it in the first place. Consult your system documentation to determine the correct capacity and speed to use.

Registered Modules

SDRAM through DDR3 modules are available in unbuffered and registered versions. Most PC motherboards are designed to use unbuffered modules, which allow the memory controller signals to pass directly to the memory chips on the module with no interference. This is not only the cheapest design, but also the fastest and most efficient. The only drawback is that the motherboard designer must place limits on how many modules (meaning module sockets) can be installed on the board, and possibly also limit how many chips can be on a module. So-called double-sided modules that really have multiple banks of chips onboard might be restricted on some systems in certain combinations.

Systems designed to accept extremely large amounts of RAM (such as servers) often require registered modules. A registered module uses an architecture that has register chips on the module that act as an interface between the actual RAM chips and the chipset. The registers temporarily hold data passing to and from the memory chips and enable many more RAM chips to be driven or otherwise placed on the module than the chipset could normally support. This allows for motherboard designs that can support many modules and enables each module to have a larger number of chips. In general, registered modules are required by server or workstation motherboards designed to support more than four sockets. One anomaly is the initial version of the AMD Athlon 64 FX processor, which also uses registered memory because its Socket 940 design was based on the AMD Opteron workstation and server processor. Subsequent Socket 939, AM2, and Socket F versions of the Athlon FX no longer require registered memory.

To provide the space needed for the buffer chips, a registered DIMM is often taller than a standard DIMM. Figure 6.10 compares a typical registered DIMM to a typical unbuffered DIMM.

Figure 6.10

Figure 6.10 A typical registered DIMM is taller than a typical unbuffered DIMM to provide room for buffer chips.

The important thing to note is that you can use only the type of module your motherboard (or chipset) is designed to support. For most, that is standard unbuffered modules or, in some cases, registered modules.

SIMM Details

The 72-pin SIMMs use a set of four or five pins to indicate the type of SIMM to the motherboard. These presence detect pins are either grounded or not connected to indicate the type of SIMM to the motherboard. Presence detect outputs must be tied to the ground through a 0-ohm resistor or jumper on the SIMM—to generate a high logic level when the pin is open or a low logic level when the motherboard grounds the pin. This produces signals the memory interface logic can decode. If the motherboard uses presence detect signals, a power-on self test (POST) procedure can determine the size and speed of the installed SIMMs and adjust control and addressing signals automatically. This enables autodetection of the memory size and speed.

Presence detect performs the same function for 72-pin SIMMs that the serial presence detect (SPD) chip does for DIMMs.

Table 6.14 shows the Joint Electronic Devices Engineering Council (JEDEC) industry-standard presence detect configuration listing for the 72-pin SIMM family. JEDEC is an organization of U.S. semiconductor manufacturers and users that sets semiconductor standards.

Table 6.14. Presence Detect Pin Configurations for 72-Pin SIMMs

Size

Speed

Pin 67

Pin 68

Pin 69

Pin 70

Pin 11

1MB

100ns

Gnd

Gnd

Gnd

1MB

80ns

Gnd

Gnd

1MB

70ns

Gnd

Gnd

1MB

60ns

Gnd

2MB

100ns

Gnd

Gnd

Gnd

2MB

80ns

Gnd

Gnd

2MB

70ns

Gnd

Gnd

2MB

60ns

Gnd

4MB

100ns

Gnd

Gnd

Gnd

Gnd

4MB

80ns

Gnd

Gnd

Gnd

4MB

70ns

Gnd

Gnd

Gnd

4MB

60ns

Gnd

Gnd

8MB

100ns

Gnd

Gnd

8MB

80ns

Gnd

8MB

70ns

Gnd

8MB

60ns

16MB

80ns

Gnd

Gnd

Gnd

16MB

70ns

Gnd

Gnd

Gnd

16MB

60ns

Gnd

Gnd

16MB

50ns

Gnd

Gnd

Gnd

Gnd

32MB

80ns

Gnd

Gnd

Gnd

32MB

70ns

Gnd

Gnd

Gnd

32MB

60ns

Gnd

Gnd

32MB

50ns

Gnd

Gnd

Gnd

Gnd

— = No connection (open)

Gnd = Ground

Pin 67 = Presence detect 1

Pin 68 = Presence detect 2

Pin 69 = Presence detect 3

Pin 70 = Presence detect 4

Pin 11 = Presence detect 5

Unfortunately, unlike the film industry, not everybody in the computer industry follows established standards. As such, presence detect signaling is not a standard throughout the PC industry. Different system manufacturers sometimes use different configurations for what is expected on these four pins. Compaq, IBM (mainly PS/2 systems), and Hewlett-Packard are notorious for this type of behavior. Many of the systems from these vendors require special SIMMs that are basically the same as standard 72-pin SIMMs, except for special presence detect requirements. Table 6.15 shows how IBM defines these pins.

Table 6.15. Presence Detect Pins for IBM 72-Pin SIMMs

67

68

69

70

SIMM Type

IBM Part Number

Not a valid SIMM

n/a

Gnd

1MB 120ns

n/a

Gnd

2MB 120ns

n/a

Gnd

Gnd

2MB 70ns

92F0102

Gnd

8MB 70ns

64F3606

Gnd

Gnd

Reserved

n/a

Gnd

Gnd

2MB 80ns

92F0103

Gnd

Gnd

Gnd

8MB 80ns

64F3607

Gnd

Reserved

n/a

Gnd

Gnd

1MB 85ns

90X8624

Gnd

Gnd

2MB 85ns

92F0104

Gnd

Gnd

Gnd

4MB 70ns

92F0105

Gnd

Gnd

4MB 85ns

79F1003 (square notch) L40-SX

Gnd

Gnd

Gnd

1MB 100ns

n/a

Gnd

Gnd

Gnd

8MB 80ns

79F1004 (square notch) L40-SX

Gnd

Gnd

Gnd

2MB 100ns

n/a

Gnd

Gnd

Gnd

Gnd

4MB 80ns

87F9980

Gnd

Gnd

Gnd

Gnd

2MB 85ns

79F1003 (square notch) L40SX

— = No connection (open)

Gnd = Ground

Pin 67 = Presence detect 1

Pin 68 = Presence detect 2

Pin 69 = Presence detect 3

Pin 70 = Presence detect 4

Because these pins can have custom variations, you often must specify IBM, Compaq, HP, or generic SIMMs when you order memory for systems using 72-pin SIMMs. Although very few (if any) of these systems are still in service, keep this information in mind if you are moving 72-pin modules from one system to another or are installing salvaged memory into a system. Also, be sure you match the metal used on the module connectors and sockets. SIMM pins can be tin or gold plated, and the plating on the module pins must match that on the socket pins; otherwise, corrosion will result.

SDR DIMM Details

SDR (single data rate) DIMMs use a completely different type of presence detect than SIMMs, called serial presence detect (SPD). It consists of a small EEPROM or flash memory chip on the DIMM that contains specially formatted data indicating the DIMM's features. This serial data can be read via the serial data pins on the DIMM, and it enables the motherboard to autoconfigure to the exact type of DIMM installed.

DIMMs can come in several varieties, including unbuffered and buffered as well as 3.3V and 5V. Buffered DIMMs have additional buffer chips on them to interface to the motherboard. Unfortunately, these buffer chips slow down the DIMM and are not effective at higher speeds. For this reason, most PC systems (those that do not use registered DIMMs) use unbuffered DIMMs. The voltage is simple—DIMM designs for PCs are almost universally 3.3V. If you install a 5V DIMM in a 3.3V socket, it would be damaged, but fortunately keying in the socket and on the DIMM prevents that.

Modern PC systems use only unbuffered 3.3V DIMMs. Apple and other non-PC systems can use the buffered 5V versions. Fortunately, the key notches along the connector edge of a DIMM are spaced differently for buffered/unbuffered and 3.3V/5V DIMMs, as shown in Figure 6.11. This prevents inserting a DIMM of the wrong type into a given socket.

Figure 6.11

Figure 6.11 The 168-pin DRAM DIMM notch key definitions.

DDR DIMM Details

The 184-pin DDR DIMMs use a single key notch to indicate voltage, as shown in Figure 6.12.

Figure 6.12

Figure 6.12 The 184-pin DDR SDRAM DIMM keying.

DDR DIMMs also use two notches on each side to enable compatibility with both low- and high-profile latched sockets. Note that the key position is offset with respect to the center of the DIMM to prevent inserting it backward in the socket. The key notch is positioned to the left, centered, or to the right of the area between pins 52 and 53. This is used to indicate the I/O voltage for the DDR DIMM and to prevent installing the wrong type into a socket that might damage the DIMM.

DDR2 DIMM Details

The 240-pin DDR2 DIMMs use two notches on each side to enable compatibility with both low- and high-profile latched sockets. The connector key is offset with respect to the center of the DIMM to prevent inserting it backward in the socket. The key notch is positioned in the center of the area between pins 64 and 65 on the front (184/185 on the back), and there is no voltage keying because all DDR2 DIMMs run on 1.8V.

DDR3 DIMM Details

The 240-pin DDR3 DIMMs use two notches on each side to enable compatibility with both low- and high-profile latched sockets. The connector key is offset with respect to the center of the DIMM to prevent inserting it backward in the socket. The key notch is positioned in the center of the area between pins 48 and 49 on the front (168/169 on the back), and there is no voltage keying because all DDR3 DIMMs run on 1.5V.

RIMM Details

The 16/18-bit RIMMs are keyed with two notches in the center. This prevents a backward insertion and prevents the wrong type (voltage) RIMM from being used in a system. Currently, all RIMMs run on 2.5V, but proposed 64-bit versions will run on only 1.8V. To allow for changes in the RIMMs, three keying options are possible in the design (see Figure 6.13). The left key (indicated as "DATUM A" in Figure 6.13) is fixed in position, but the center key can be in three different positions spaced 1mm or 2mm to the right, indicating different types of RIMMs. The current default is option A, as shown in Figure 6.13 and Table 6.16, which corresponds to 2.5V operation.

Figure 6.13

Figure 6.13 RIMM keying options.

Table 6.16. Possible Keying Options for RIMMs

Option

Notch Separation

Description

A

11.5mm

2.5V RIMM

B

12.5mm

Reserved

C

13.5mm

Reserved

RIMMs incorporate an SPD device, which is essentially a flash ROM onboard. This ROM contains information about the RIMM's size and type, including detailed timing information for the memory controller. The memory controller automatically reads the data from the SPD ROM to configure the system to match the RIMMs installed.

Figure 6.14 shows a typical PC RIMM installation. The RDRAM controller and clock generator are typically in the motherboard chipset North Bridge component. As you can see, the Rambus memory channel flows from the memory controller through each of up to three RIMM modules in series. Each module contains 4, 8, 16, or more RDRAM devices (chips), also wired in series, with an onboard SPD ROM for system configuration. Any RIMM sockets without a RIMM installed must have a continuity module, shown in the last socket in Figure 6.13. This enables the memory bus to remain continuous from the controller through each module (and, therefore, each RDRAM device on the module) until the bus finally terminates on the motherboard. Note how the bus loops from one module to another. For timing purposes, the first RIMM socket must be 6" or less from the memory controller, and the entire length of the bus must not be more than it would take for a signal to go from one end to another in four data clocks, or about 5ns.

Figure 6.14

Figure 6.14 Typical RDRAM bus layout showing a RIMM and one continuity module.

Interestingly, Rambus does not manufacture the RDRAM devices (the chips) or the RIMMs; that is left to other companies. Rambus is merely a design company, and it has no chip fabs or manufacturing facilities of its own. It licenses its technology to other companies who then manufacture the devices and modules.

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