MTA9ADF1G72PKIZ-2G6B1 Datasheet MTA9ADF1G72PKIZ-2G6B1 | P13-P15

Address Mapping to DRAM

Address Mirroring

To achieve optimum routing of the address bus on DDR4 multi rank modules, the ad-

dress bus will be wired as shown in the table below, or mirrored. For quad rank mod-

ules, ranks 1 and 3 are mirrored and ranks 0 and 2 are non-mirrored. Highlighted ad-

dress pins have no secondary functions allowing for normal operation when cross-

wired. Data is still read from the same address it was written. However, Load Mode op-

erations require a specific address. This requires the controller to accommodate for a

rank that is "mirrored." Systems may reference DDR4 SPD to determine if the module

has mirroring implemented or not. See the JEDEC DDR4 SPD specification for more de-

tails.

Table 8: Address Mirroring

Edge Connector Pin DRAM Pin, Non-mirrored DRAM Pin, Mirrored

A0 A0 A0

A1 A1 A1

A2 A2 A2

A3 A3 A4

A4 A4 A3

A5 A5 A6

A6 A6 A5

A7 A7 A8

A8 A8 A7

A9 A9 A9

A10 A10 A10

A11 A11 A13

A13 A13 A11

A12 A12 A12

A14 A14 A14

A15 A15 A15

A16 A16 A16

A17 A17 A17

BA0 BA0 BA1

BA1 BA1 BA0

BG0 BG0 BG1

BG1 BG1 BG0

8GB (x72, ECC, SR) 288-Pin DDR4 VLP MiniRDIMM

Address Mapping to DRAM

CCMTD-341111752-10428

adf9c1gx72pkiz.pdf - Rev. D 8/18 EN

Micron Technology, Inc. reserves the right to change products or specifications without notice.

Registering Clock Driver Operation

Registered DDR4 SDRAM modules use a registering clock driver device consisting of a

specification.

To reduce the electrical load on the host memory controller's command, address, and

control bus, Micron's RDIMMs utilize a DDR4 registering clock driver (RCD). The RCD

presents a single load to the controller while redriving signals to the DDR4 SDRAM de-

vices, which helps enable higher densities and increase signal integrity. The RCD also

provides a low-jitter, low-skew PLL that redistributes a differential clock pair to multiple

differential pairs of clock outputs.

Control Words

The RCD device(s) used on DDR4 RDIMMs, LRDIMMs, and NVDIMMs contain configu-

ration registers known as control words, which the host uses to configure the RCD

based on criteria determined by the module design. Control words can be set by the

host controller through either the DRAM address and control bus or the I

C bus inter-

face. The RCD I

C bus interface resides on the same I

C bus interface as the module

temperature sensor and EEPROM.

Parity Operations

The RCD includes a parity-checking function that can be enabled or disabled in control

word RC0E. The RCD receives a parity bit at the DPAR input from the memory control-

ler and compares it with the data received on the qualified command and address in-

puts; it indicates on its open-drain ALERT_n pin whether a parity error has occurred. If

parity checking is enabled, the RCD forwards commands to the SDRAM when no parity

error has occurred. If the parity error function is disabled, the RCD forwards sampled

commands to the SDRAM regardless of whether a parity error has occurred. Parity is al-

so checked during control word WRITE operations unless parity checking is disabled.

Rank Addressing

The chip select pins (CS_n) on Micron's modules are used to select a specific rank of

DRAM. The RDIMM is capable of selecting ranks in one of three different operating

modes, dependant on setting DA[1:0] bits in the DIMM configuration control word lo-

cated within the RCD. Direct DualCS mode is utilized for single- or dual-rank modules.

For quad-rank modules, either direct or encoded QuadCS mode is used.

8GB (x72, ECC, SR) 288-Pin DDR4 VLP MiniRDIMM

Registering Clock Driver Operation

CCMTD-341111752-10428

adf9c1gx72pkiz.pdf - Rev. D 8/18 EN

Micron Technology, Inc. reserves the right to change products or specifications without notice.

Temperature Sensor with SPD EEPROM Operation

Thermal Sensor Operations

The integrated thermal sensor continuously monitors the temperature of the module

PCB directly below the device and updates the temperature data register. Temperature

data may be read from the bus host at any time, which provides the host real-time feed-

back of the module's temperature. Multiple programmable and read-only temperature

registers can be used to create a custom temperature-sensing solution based on system

requirements and JEDEC JC-42.2.

EVENT_n Pin

The temperature sensor also adds the EVENT_n pin (open-drain), which requires a pull-

up to V

DDSPD

. EVENT_n is a temperature sensor output used to flag critical events that

can be set up in the sensor’s configuration registers. EVENT_n is not used by the serial

presence-detect (SPD) EEPROM.

EVENT_n has three defined modes of operation: interrupt, comparator, and TCRIT. In

interrupt mode, the EVENT_n pin remains asserted until it is released by writing a 1 to

the clear event bit in the status register. In comparator mode, the EVENT_n pin clears

itself when the error condition is removed. Comparator mode is always used when the

temperature is compared against the TCRIT limit. In TCRIT only mode, the EVENT_n

pin is only asserted if the measured temperature exceeds the TCRIT limit; it then re-

mains asserted until the temperature drops below the TCRIT limit minus the TCRIT

hysteresis.

SPD EEPROM Operation

DDR4 SDRAM modules incorporate SPD. The SPD data is stored in a 512-byte, JEDEC

JC-42.4-compliant EEPROM that is segregated into four 128-byte, write-protectable

blocks. The SPD content is aligned with these blocks as shown in the table below.

Block Range Description

0 0–127 000h–07Fh Configuration and DRAM parameters

1 128–255 080h–0FFh Module parameters

2 256–319 100h–13Fh Reserved (all bytes coded as 00h)

320–383 140h–17Fh Manufacturing information

3 384–511 180h–1FFh End-user programmable

The first 384 bytes are programmed by Micron to comply with JEDEC standard JC-45,

"Appendix X: Serial Presence Detect (SPD) for DDR4 SDRAM Modules." The remaining

128 bytes of storage are available for use by the customer.

The EEPROM resides on a two-wire I

C serial interface and is not integrated with the

memory bus in any manner. It operates as a slave device in the I

C bus protocol, with all

operations synchronized by the serial clock. Transfer rates of up to 1 MHz are achieva-

ble at 2.5V (NOM).

Micron implements reversible software write protection on DDR4 SDRAM-based mod-

ules. This prevents the lower 384 bytes (bytes 0 to 383) from being inadvertently pro-

grammed or corrupted. The upper 128 bytes remain available for customer use and are

unprotected.

8GB (x72, ECC, SR) 288-Pin DDR4 VLP MiniRDIMM

Temperature Sensor with SPD EEPROM Operation

CCMTD-341111752-10428

adf9c1gx72pkiz.pdf - Rev. D 8/18 EN

Micron Technology, Inc. reserves the right to change products or specifications without notice.

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MTA9ADF1G72PKIZ-2G6B1

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MODULE DDR4 8GB MINIRDIMM VLP

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