The invention relates to a decoder circuit, and in particular, to a low power decoder circuit for a communication bus.
As integrated circuit technology is scaled to provide increased density on a chip, the on-chip interconnects tend to become narrower and narrower. These trends lead to an increase in coupling capacitance with neighbouring wires, which in turn leads to increased interference or crosstalk between wires.
A well known example of such interference is the increase in mutual capacitance (Cm) between neighbouring conductors of data communication devices, such as communication buses. The increase in mutual capacitance not only has a degrading effect on signal integrity, but also increases the overall power consumption of the data communication device. The increase in component density, together with the downscaling of the semiconductor technology dimensions, add to the overall power consumption of an integrated circuit and associated electronic device. In fact, integrated circuit power consumption is increasing to such an extent that meeting the power demands without jeopardizing integrated circuit integrity is becoming a major issue. Therefore, measures to reduce the power consumption of an integrated circuit have become increasingly important.
In a fault-tolerant bus structure such as that shown in
The unequal flight times are caused by the capacitance between the bus lines, and the different switching patterns between the various wires on the communication bus 3, ie crosstalk. In addition, the circuitry in the encoder S, (for example parity trees in fault tolerant encoders), can also contribute to the different flight times.
Therefore, when the victim wire 19 switches from logic 0 to 1, the moment at which the receiving end switches from 0 to 1 depends on the switching behaviour of the aggressor wires 21, 23.
In a first order approach, five different delay times can be distinguished for the victim wire 19. This is illustrated in the table shown in
For example, the fastest switching time (or shortest delay) is experienced when both aggressor wires 21, 23 switch in the same direction as the victim wire 19, as shown in the first row in the table. Conversely, the slowest switching (or longest delay) is experienced when both aggressor wires 21, 23 switch in the opposite direction to the victim wire 19, as shown in the last row of the table.
The flight-time fluctuations mentioned above can have a degrading effect on circuits such as decoders, as will be explained below with reference to
The control signal 57 is fed to a plurality of multiplexers 590, 591, 592, 593 which act as a correction circuit. Each Multiplexer 590, 591, 592, 593 receives a respective input data bit (D0, D1, D2, D3) and a corresponding copy of the data bit (copy0, copy1, copy2, copy3). The control signal 57 controls whether each multiplexer outputs the data bit or the copy of the data bit. Thus, if the data bit and its copy have different flight times, the output data signals (out0, out1, out2, out3) will also exhibit glitches, which will be fed into the next circuit.
It will be appreciated that the glitches shown above all contribute to an unnecessary increase in power consumption in the decoder circuit and in the circuitry thereafter. Similar glitches are also experienced in other types of decoders, for example a hamming decoder. Also, non-fault tolerant codes may suffer from the same problem.
The aim of the present invention is therefore to provide a low power decoder circuit that does not suffer from the disadvantages mentioned above.
According to a first aspect of the present invention, there is provided a decoder circuit for a communication bus, the decoder circuit receiving a plurality of data signals from the communication bus, the data signals being susceptible of being received at different times, wherein the decoder circuit comprises:
a correction circuit for correcting one or more of the input signals;
a control signal for controlling the correction circuit;
a gating circuit, the gating circuit arranged in the path of the control signal; and
a gating control signal for controlling the gating circuit such that the control signal for controlling the correction circuit is blocked until a predetermined time.
The invention has the advantage of reducing unwanted glitches in the decoder circuit, thereby reducing power consumption.
According to another aspect of the present invention, there is provided a method of reducing power consumption in a decoder circuit for a communication bus, the decoder circuit receiving a plurality of data signals from the communication bus, the data signals being susceptible of being received at different times, wherein the decoder circuit comprises a correction circuit for correcting one or more of the input signals and a control signal for controlling the correction circuit, wherein the method comprises the steps of providing a gating circuit in the path of the control signal, and controlling the gating circuit with a gating control signal, such that the control signal for controlling the correction circuit is blocked until a predetermined time.
For a better understanding of the present invention, and to show more clearly how it may be carried into effect, reference will now be made, by way of example, to the accompanying drawings, in which:
As with the dual-rail decoder shown in
However, rather than connecting the control signal 57 from the exclusive OR gate 55 directly to the multiplexers 590, 591, 592, 593, the control signal 57 is instead connected to a gating circuit 71. The gating circuit 71, for example an AND gate, receives the control signal 57 as a first input signal. The gating circuit 71 also receives a second input signal in the form of a gating control signal 73. The gating control signal 73 is delayed by a predetermined amount. Preferably, the gating control signal is delayed by an amount corresponding to the worst case delay in the input data signals 43. In other words, the gating control signal 73 is delayed by an amount corresponding to the worst flight time of the signals on the communication bus.
Thus, the gating control signal 73 does not control the gating circuit until such time as all of the data signals have become stable, ie until the last transition on the data signal 43 has occurred. As a result, the output signal 75 from the gating circuit 71 is not produced until all the data signals 43 have settled. The output signal 75 is therefore, in effect, a delayed version of the control signal 57.
Preferably, the gating control signal 73 is a delayed version of a system clock signal. However, it will be appreciated that the gating control signal 73 can be generated in other ways.
The delayed control signal 75 is fed to a plurality of multiplexers 590, 591, 592, 593, in a similar way to that previously described in
The decoder circuit described above therefore has the advantage of consuming less power than the decoder circuit described in
In addition to blocking the control signal for the correction circuit as described above, one or more additional gating circuits can also be provided in the circuit as described below in relation to
The output signal 57 of the exclusive OR gate 55 is fed to the multiplexers 590 to 59N, which select either the input data signal DN or the copy of the data signal copyN. If desired, this signal can be gated so that the control signal is blocked until the input signals are stable, as described above in
According to this embodiment, however, a number of gating circuits 77copy0/77D0 to 77copyN/77DN are connected in the path of one or more of the input data signals 43. Each of the gating circuits 77copy0/77D0 to 77copyN/77DN is controlled by a gating control signal 73. As with
Although this embodiment requires more gates to suppress glitches compared to the circuit of
The control signal 57 outputted from the exclusive OR gate 55 is fed to the multiplexers 590 to 59N, which select either the input data signal DN or the copy data signal copyN. As before, this signal can be gated so that the control signal is blocked until the input signals are stable, as described above in
According to this embodiment, however, a number of gating circuits 790 to 79N are connected in the output path of each multiplexer 590 to 59N. In other words, the glitches are suppressed on the data lines after they have been selected by the multiplexers 590 to 59N. This embodiment has the advantage of requiring less gating circuits than the second embodiment shown in
It is noted that any combination of the three embodiments described above is also possible. For example, if the embodiment described in
The invention can also be used with other types of decoding circuits.
Preferably, the gating circuits 115, 117 and 119 are placed between the parity trees and the syndrome decoder. For example, gating circuit 115 receives the first parity signal 109 and the gating control signal 73. Gating circuit 117 receives the second parity signal 111 and the gating control signal 73, while gating circuit 119 receives the third parity signal 113 and the gating control signal 73. In this manner, the parity signals 109, 111, 113 are blocked from passing to the syndrome decoder until a predetermined time controlled by the gating control signal 73. Preferably, the gating control signal is triggered after all of the input signals are stable. Alternatively, the gating control signal 73 can be triggered after the majority of the input signals are stable. Although this alternative only allows partial reduction in glitches, and hence only partial power reduction, this solution has less of a speed penalty.
The embodiment described above provides a hamming decoder that has a reduced number of glitches and hence a reduced power consumption. For the (7, 4) optimal hamming decoder described in the embodiment, it is noted that three gating circuits were provided for the three parity trees. For larger wordsizes, however, hamming decoders become more attractive since the number of additional parity trees is proportional to the log of the number of data bits. Hence, for 32 data bits, only six parity trees and thus six gating circuits are required.
Although the preferred embodiments have been described in relation to a dual-rail decoder circuit and a hamming decoder, it will be appreciated that the invention is also applicable to other types of decoder circuits. The invention is also suitable for use with non-fault tolerant codes.
In addition, although the preferred embodiments of the invention describe the gating circuit as an AND gate, it will be appreciated that other selection logic or latch circuits may be used for this purpose.
Furthermore, although some of the embodiments have been described with reference to a decoder circuit receiving a predetermined number data signals, it will be appreciated that the communication can work with any number of data signals.
The invention described above has the advantage of reducing power consumption in a decoder circuit, by reducing the number of glitches generated in the decoder circuit.
It is also noted that, although the preferred embodiments refer to reducing power consumption by generating the gating control signal 73 at a predetermined time corresponding to when all of the input data signals are stable, alternatively, the gating control signal 73 can be triggered after only some of the input signals are deemed to be stable. Although this alternative only allows partial reduction in glitches, and hence only partial power reduction, this solution has less of a speed penalty.
It is also noted that, although the preferred embodiments refer to the gating control signal being generated from a delayed version of the system clock, the gating control signal may also be generated using other methods, for example using the input data and/or parity bits. This alternative provides a self-timed solution.
Number | Date | Country | Kind |
---|---|---|---|
03102499.5 | Aug 2003 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB04/51404 | 8/5/2004 | WO | 2/7/2006 |