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デスクトップ HP 386819-001 - ProSignia - 720のPDF 概要をオンラインで閲覧またはダウンロードできます。HP 386819-001 - ProSignia - 720 20 ページ。 Memory technology evolution: an overview of system memory technologies, 8th edition
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Double transition clocking
Standard DRAM transfers one data bit to the bus on the rising edge of the bus clock signal, while
DDR-1 uses both the rising and falling edges of the clock to trigger the data transfer to the bus
(Figure 10). This technique, known as double transition clocking, delivers twice the bandwidth of
SDRAM without increasing the clock frequency. DDR-1 has theoretical peak data transfer rates of 1.6
and 2.1 GB/s at clock frequencies of 100 MHz and 133 MHz, respectively.
Figure 10. Data transfer rate comparison between SDRAM (with burst mode access) and DDR SDRAM
SSTL_2 low-voltage signaling technology
Another difference between SDRAM and DDR-1 is the signaling technology. Instead of using a 3.3-V
operating voltage, DDR-1 uses a 2.5-V signaling specification known as Stub Series-Terminated
Logic_2 (SSTL_2). This low-voltage signaling results in lower power consumption and improved heat
dissipation.
Stobe-based data bus
SSTL_2 signaling allows DDR-1 to run at faster speeds than traditional SDRAM. In addition, DDR-1
uses a delay-locked loop (one for every 16 outputs) to provide a data strobe signal as data becomes
valid on the SDRAM pins. The memory controller uses the data strobe signal to locate data more
accurately and resynchronize incoming data from different DIMMs.
DDR-1 operates at transfer rates of 400 Mb/s, or 3.2 GB/s. Although the data bus is capable of
running at these speeds, the command bus cannot. Tight system timing requirements were alleviated
on the data bus by using strobes. However, the command bus does not use a strobe and must still
meet setup times to a synchronous clock. Thus, at a data rate of 400 Mb/s, the command bus must
operate at 200 MHz.
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