• Welcome to TechPowerUp Forums, Guest! Please check out our forum guidelines for info related to our community.

JEDEC Releases LPDDR4 Standard for Low Power Memory Devices

btarunr

Editor & Senior Moderator
Staff member
Joined
Oct 9, 2007
Messages
47,233 (7.55/day)
Location
Hyderabad, India
System Name RBMK-1000
Processor AMD Ryzen 7 5700G
Motherboard ASUS ROG Strix B450-E Gaming
Cooling DeepCool Gammax L240 V2
Memory 2x 8GB G.Skill Sniper X
Video Card(s) Palit GeForce RTX 2080 SUPER GameRock
Storage Western Digital Black NVMe 512GB
Display(s) BenQ 1440p 60 Hz 27-inch
Case Corsair Carbide 100R
Audio Device(s) ASUS SupremeFX S1220A
Power Supply Cooler Master MWE Gold 650W
Mouse ASUS ROG Strix Impact
Keyboard Gamdias Hermes E2
Software Windows 11 Pro
JEDEC Solid State Technology Association, the global leader in standards development for the microelectronics industry, today announced the publication of JESD209-4 Low Power Double Data Rate 4 (LPDDR4). Designed to significantly boost memory speed and efficiency for mobile computing devices such as smartphones, tablets, and ultra-thin notebooks, LPDDR4 will eventually operate at an I/O rate of 4266 MT/s, twice that of LPDDR3.

The new interface promises to have an enormous impact on the performance and capabilities of next-generation portable electronics. "LPDDR4 represents a dramatic performance increase," said Mian Quddus, Chairman, JEDEC Board of Directors. "It is intended to meet the power, bandwidth, packaging, cost and compatibility requirements of the world's most advanced mobile systems." Developed by JEDEC's JC-42.6 Subcommittee for Low Power Memories, the JESD209-4 LPDDR4 standard can be downloaded from the JEDEC website for free by clicking here.

The market for mobile computing continues to grow, and with it the demand for ever faster devices and ever longer operation on a single charge. LPDDR4 launches with an I/O data rate of 3200 MT/s and a target speed of 4266 MT/s, compared to 2133 MT/s for LPDDR3. To achieve this performance, the members of the committee had to completely redesign the architecture, going from a one-channel die with 16 bits per channel to a two-channel die with 16 bits per channel, for a total of 32 bits.

"LPDDR3 was an evolutionary change from LPDDR2. With LPDDR4, the architecture is completely different," said Hung Vuong, Chairman of JC-42.6. "We knew the only way to achieve the performance that the industry required was to make a total departure from previous generations." The two-channel architecture reduces the distance data signals must travel from the memory array to the I/O bond pads. This reduces the power required to transmit the large amount of data the LPDDR4 interface requires. Because most of the area of a memory device is taken up by the memory array, doubling the interface area has a minimal impact on the overall footprint.

The two-channel architecture also allows the clock and address bus to be grouped together with the data bus. Thus, the skew between data bus to the clock and address bus is minimized, allowing the LPDDR4 device to reach a higher data rate. This saves power and improves timing margins compared to the LPDDR3 architecture.

A new approach to signaling
Recognizing that extending the LPDDR3 interface to higher frequencies would consume too much power, the JEDEC committee decided to implement a significant change in LPDDR4's I/O signaling to low-voltage swing-terminated logic (LVSTL). LPDDR4's LVSTL I/O signaling voltage of 367 or 440mV is less than 50% the I/O voltage swing of LPDDR3. This reduces power while enabling high-frequency operation. In addition, by using Vssq termination and data bus inversion (DBI), termination power can be minimized since any I/O signal driving a "0" consumes no termination power.

Several other steps were taken to save power. The operating voltage was reduced from the 1.2V of previous generations to 1.1V. Also, the standard was specifically designed to enable power-efficient operation at a wide range of frequencies. The I/O can operate in un-terminated mode at low frequencies with a reduced voltage swing, and the standard allows rapid switching between operating points so the lower frequency operation can be used whenever possible.

This rapid switching is enabled by the addition of frequency set points (FSPs). LPDDR4 specifies two FSPs, which are copies of all the DRAM registers that store operating parameters which might need to be changed for operation at two different frequencies. Once both operating frequencies are trained and the parameters stored in each of the two corresponding FSPs, switching between the frequencies can be accomplished by a single mode register write. This reduces the latency for frequency changes, and enables the system to operate at the optimal speed for the workload more often.

"It supports end-user flexibility," noted Vuong. "Some designers like to run their devices as fast as they can and then put them to sleep. Others like to run at lower frequencies - and lower power - when possible. A process might take a little longer but that's a trade-off they're willing to make. We designed LPDDR4 to be flexible enough to allow the end-user to decide what they want to do." With that flexibility comes superior performance - an LPDDR4 device, at a similar data rate, will consume less power than an LPDDR3 device.

Key specifications include:
  • Two-channel architecture
  • Internal Vref supplies for CA and DQ
  • Data Bus Inversion (DBI-DC)
  • ODT for CA and DQ
  • I/O throughput: 3200 MT/s, rising to 4266 MT/s
  • Signaling voltage: 367mV or 440mV
  • Operating voltage: 1.1V
  • Pre-fetch size: 32B per channel
  • Topology: Point to point, PoP, MCP
  • Max I/O capacitance: 1.3pF
  • Write leveling
  • 6-pin SDR CA bus CA training (12 pins per two channels)
  • As with previous low-power DRAM generations, LPDDR4 does not require a delay-locked loop (DLL) or phase-locked loop (PLL)
LPDDR4 Workshop
To facilitate understanding and adoption of the LPDDR4 standard, JEDEC is hosting an LPDDR4 Workshop in Santa Clara, CA on September 23, 2014.

View at TechPowerUp Main Site
 
Joined
Jan 5, 2013
Messages
895 (0.21/day)
This new specification will be useful only for applications where existing LV DDR3 is a system bottleneck. There are NOT many places where this is the case but down the road 5-10 years this new spec DRAM might be of significance.
 

Aquinus

Resident Wat-man
Joined
Jan 28, 2012
Messages
13,169 (2.81/day)
Location
Concord, NH, USA
System Name Apollo
Processor Intel Core i9 9880H
Motherboard Some proprietary Apple thing.
Memory 64GB DDR4-2667
Video Card(s) AMD Radeon Pro 5600M, 8GB HBM2
Storage 1TB Apple NVMe, 4TB External
Display(s) Laptop @ 3072x1920 + 2x LG 5k Ultrafine TB3 displays
Case MacBook Pro (16", 2019)
Audio Device(s) AirPods Pro, Sennheiser HD 380s w/ FIIO Alpen 2, or Logitech 2.1 Speakers
Power Supply 96w Power Adapter
Mouse Logitech MX Master 3
Keyboard Logitech G915, GL Clicky
Software MacOS 12.1
Also, the standard was specifically designed to enable power-efficient operation at a wide range of frequencies. The I/O can operate in un-terminated mode at low frequencies with a reduced voltage swing, and the standard allows rapid switching between operating points so the lower frequency operation can be used whenever possible.

That's cool. Lowering the memory speed during low power/low demand operation surely could reduce power consumption by the memory controller as well as the DRAM.
 
Top