Double data rate: Difference between revisions
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In [[computing]], a [[computer bus]] operating with '''double data rate''' transfers data on both the rising and falling edges of the [[clock signal]], effectively nearly doubling the data transmission rate without having to deal with the additional problems of [[timing skew]] that increasing the number of data lines would introduce. This is also known as '''double pumped''', '''dual-pumped''', and '''double transition'''. | In [[computing]], a [[computer bus]] operating with '''double data rate''' transfers data on both the rising and falling edges of the [[clock signal]], effectively nearly doubling the data transmission rate without having to deal with the additional problems of [[timing skew]] that increasing the number of data lines would introduce. This is also known as '''double pumped''', '''dual-pumped''', and '''double transition'''. | ||
This technique has been used for the [[Front side bus]], [[SCSI#Ultra-3|Ultra-3 SCSI]], the [[Accelerated Graphics Port | This technique has been used for the [[Front side bus]], [[SCSI#Ultra-3|Ultra-3 SCSI]], the [[Accelerated Graphics Port]] (AGP) bus, [[DDR SDRAM]], and the [[HyperTransport]] version 3.0 bus. | ||
An alternative to double or quad pumping is to make the link [[Self-clocking signal|self-clocking]]. This tactic was chosen by [[InfiniBand]] and [[PCI Express]]. | An alternative to double or [[Quadruple data rate|quad pumping]] is to make the link [[Self-clocking signal|self-clocking]]. This tactic was chosen by [[InfiniBand]] and [[PCI Express]]. | ||
It is often difficult to know how to refer to the speed of a double-pumped bus. Discussing the raw bandwidth of a bus is less ambiguous than comparing clock speed and transfers per second as this also takes into account the width of the bus: thus [[DDR SDRAM]] that runs on a clock signal of 100 MHz, with data transfer the same as [[SDR SDRAM]] running at about 200 MHz, is called DDR-200 and PC-1600, referring to the [[peak bandwidth]]. However, this number does not take into account the bus protocol overhead or [[Latency|latencies]], both of which can reduce the effective bandwidth of a bus to a fraction of the raw bandwidth. | It is often difficult to know how to refer to the speed of a double-pumped bus. Discussing the raw bandwidth of a bus is less ambiguous than comparing clock speed and transfers per second as this also takes into account the width of the bus: thus [[DDR SDRAM]] that runs on a clock signal of 100 MHz, with data transfer the same as [[SDR SDRAM]] running at about 200 MHz, is called DDR-200 and PC-1600, referring to the [[peak bandwidth]]. However, this number does not take into account the bus protocol overhead or [[Latency|latencies]], both of which can reduce the effective bandwidth of a bus to a fraction of the raw bandwidth. | ||
While a double-pumped bus can nearly double peak bandwidth, it does nothing for [[latency (engineering)|latency]], because it takes the same amount of time for the first "word" to arrive from memory. By contrast, actually doubling the speed of the bus reduces latency, because the individual bits of data move across the bus faster. However, doubling the clock speed of a bus is a difficult engineering challenge. | While a double-pumped bus can nearly double peak bandwidth, like widening the bus, it does nothing for [[latency (engineering)|latency]], because it takes the same amount of time for the first "word" to arrive from memory. By contrast, actually doubling the speed of the bus reduces latency, because the individual bits of data move across the bus faster. However, doubling the clock speed of a bus is a difficult and expensive engineering challenge. | ||
== See also == | == See also == |
Revision as of 16:30, 11 January 2007
In computing, a computer bus operating with double data rate transfers data on both the rising and falling edges of the clock signal, effectively nearly doubling the data transmission rate without having to deal with the additional problems of timing skew that increasing the number of data lines would introduce. This is also known as double pumped, dual-pumped, and double transition.
This technique has been used for the Front side bus, Ultra-3 SCSI, the Accelerated Graphics Port (AGP) bus, DDR SDRAM, and the HyperTransport version 3.0 bus.
An alternative to double or quad pumping is to make the link self-clocking. This tactic was chosen by InfiniBand and PCI Express.
It is often difficult to know how to refer to the speed of a double-pumped bus. Discussing the raw bandwidth of a bus is less ambiguous than comparing clock speed and transfers per second as this also takes into account the width of the bus: thus DDR SDRAM that runs on a clock signal of 100 MHz, with data transfer the same as SDR SDRAM running at about 200 MHz, is called DDR-200 and PC-1600, referring to the peak bandwidth. However, this number does not take into account the bus protocol overhead or latencies, both of which can reduce the effective bandwidth of a bus to a fraction of the raw bandwidth.
While a double-pumped bus can nearly double peak bandwidth, like widening the bus, it does nothing for latency, because it takes the same amount of time for the first "word" to arrive from memory. By contrast, actually doubling the speed of the bus reduces latency, because the individual bits of data move across the bus faster. However, doubling the clock speed of a bus is a difficult and expensive engineering challenge.
See also
- Quadruple data rate
- DDR SDRAM, DDR2 SDRAM and DDR3 SDRAM are all types of RAM utilizing DDR.