KR100558262B1 - Low power crossbar switch - Google Patents

Abstract

The present invention relates to a low-power crossbar switch, in which the entire crossbar switch is divided into a plurality of small groups, and only the group in which data is actually switched by the control signal of the scheduler is input signal input to each group and output signal output from each group. By controlling the activation, the driving load is limited to each group, thereby reducing power consumption and improving operating speed.

Crossbar, switch, low-power, speed, drive load

Description

LOW POWER CROSSBAR SWITCH             

1 is a configuration diagram showing a conventional general crossbar switch.

Figure 2 is a block diagram showing a low power crossbar switch according to the present invention.

3 is a circuit diagram illustrating an input control unit of each group in the low power crossbar switch according to the present invention.

4 is a circuit diagram illustrating an output control unit of each group in a low power crossbar switch according to the present invention.

   -Explanation of symbols for the main parts of the drawings-

10; Scheduler

21,22,23,24: first to fourth input control unit

31,32,33,34: first to fourth output control unit

Grant1 to Grant8: 1st to 8th control signals

IN1 to IN8: 1st to 8th input ports

MUX1 to MUX8: First to Eighth Multiplexers

OR1 to OR8: first to eighth gate

OUT1 to OUT8: 1st to 8th output ports

S1 to S4: first to fourth switches

TILE1-1, TILE1-2, TILE2-1, TILE2-2: 1st to 4th group

The present invention relates to a low-power crossbar switch, and more particularly, to divide the entire crossbar switch into a plurality of small groups, and to actually input data into each group and output signals from each group by the control signal of the scheduler. The present invention relates to a low-power crossbar switch that controls driving groups to be activated so that the driving load is limited to each group to reduce power consumption and improve operation speed.

Crossbar switches are arranged in a vertical and horizontal shape, and are used as an essential component to form a network between multiprocessors and communication structures in on-chip as well as switches or routers used in a communication network.

1 is a configuration diagram showing a conventional general crossbar switch.

The crossbar fabric shown here is an 8x8 structure, assuming that data is to be transferred from the third input port IN3 to the eighth output port OUT8. First, the eighth output port OUT8 is applied to the REQ3 input of the scheduler 10. Information about going to The scheduler 10 selects one input port through an internal algorithm among the input ports for which the eighth output port OUT8 is desired.

Herein, when the third input port IN3 is selected, the scheduler 10 loads information for selecting the third input port IN3 to the control signal Grant8 <1: 8> output having 8 bits. That is, only Grant8 <3> entering the gate of the transistor of N38 becomes '1' and the remaining Grant8 <1: 2> and Grant8 <4: 8> are set to '0'.

Then, a crossbar is connected to the eighth output port OUT8 from the third input port IN3 along the dotted line to form a path.

In this case, the load that the input driver circuit must drive is the wire capacitance of the input horizontal line itself, the junction capacitance of the eight transistors that depend on the input horizontal line, and the output. Charge / discharge the junction capacitance of 16 transistors and the wire capacitance of input / output lines with the wire capacitance of the vertical line itself and the junction capacitance of 8 transistors that depend on the output vertical line. Discharge).

As a result, such a load increases linearly as the number of ports of the crossbar fabric increases, resulting in an increase in power consumption of the overall crossbar fabric, and at the same time, there is a problem in that the operation speed of the crossbar fabric is reduced.

The present invention was created to solve the above problems, and an object of the present invention is to divide the entire crossbar switch into a plurality of small groups, and to control the scheduler to control the input signal inputted to each group and the output signal outputted from each group. The present invention provides a low-power crossbar switch capable of reducing power consumption and improving operating speed by limiting driving load to each group by controlling only a group in which data is actually switched by a signal.

The present invention for achieving the above object is a crossbar switch composed of a crossbar switch arranged in a vertical and horizontal direction of the input line and an output line and a scheduler for controlling the operation of the crossbar switch, a plurality of crossbar switches arranged in a vertical and horizontal An input control unit for combining one group with a control signal of a scheduler so that one of the plurality of groups is selected to apply an input signal through the input port, and a plurality of groups for receiving the output signals of the plurality of groups The combination of the multiplexer and the control signal of the scheduler is characterized in that the output control unit for selecting one of the plurality of multiplexer to output the output signal through the output port.

In the present invention, the input control unit is characterized by consisting of an or gate receiving the same input port selection bits, respectively, in the control signal of the scheduler corresponding to each group, and a switch for controlling the input signal by the output signal of the or gate.

In the present invention, the output control unit is composed of an orgate for enabling the multiplexer by receiving input port selection bits corresponding to each group for each control signal of the scheduler corresponding to each group.

According to the present invention, one of a plurality of groups selected by the control signal of the scheduler is selected so that an input signal input through the input port is applied to output an output signal through the output port, and then through the entire crossbar switch. Instead, as only the group in which data is actually switched is activated, the driving load is limited to the selected group, thereby reducing power consumption and improving operation speed.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only and the same parts as in the conventional configuration using the same reference numerals and names.

Figure 2 is a block diagram showing a low power crossbar switch according to the present invention, Figure 3 is a circuit diagram showing the input control unit of each group in the low power crossbar switch according to the present invention, Figure 4 is a low power crossbar switch according to the present invention A circuit configuration diagram showing an output control unit of each group.

As shown here, the crossbar switch of the 8x8 structure includes the first group TILE1-1 arranged as the input ports IN1 to IN4 and the output ports OUT1 to OUT4, the input ports IN1 to IN4, and the output port. The second group TILE1-2 arranged in the range of OUT5 to OUT8, the third group TILE2-1 arranged in the input port IN5 to IN8 and the output ports OUT1 to OUT4, and the input port ( It is separated into the fourth group TILE2-2 arranged with IN5 to IN8 and output ports OUT5 to OUT8.

In order to control the operation of the crossbar switch, the first and third groups TILE1-1 according to the 8-bit first to eighth control signals Grant1 <1: 8> to Grant8 <1: 8> of the scheduler 10. To fourth inputs for selecting an input signal through the first to eighth input ports IN1 to IN8 by selecting a second or fourth group TILE2-1) or second and fourth groups TILE1-2 and TILE2-2. The control parts 21-24 are provided.

In this case, the first input controller 21 selects the same input port from the first to fourth control signals Grant1 to Grant4 of the scheduler 10 corresponding to the first group TILE1-1 as shown in FIG. 3. First to fourth switches S1 to S4 for controlling the input signal by the output signals of the first to fourth or gates OR1 to OR4 and the first to fourth or gates OR1 to OR4 that receive the bits. )

For example, in order to select the first input port IN1 of the first group TILE1-1 from the first input controller 21, the first to fourth control signals Grant1 <1>, Grant2 <1>, If any one of Grant3 <1> and Grant4 <1> is input and the signal of '1' is outputted, the output of the first gate OR1 becomes '1' and the first switch S1 is enabled. The first input port IN1 of the first group TILE1-1 is selected to be configured to apply an input signal, and the configuration for selecting the second to fourth input ports IN2 to IN4 is configured in the same manner. .

In addition, the first to fourth input control units 21 to 24 for selecting the input ports of the first to fourth groups TILE1-1, TILE1-2, TILE2-1, and TILE2-2 are configured in the above manner. do.

First to eighth output signals from the first to fourth groups TILE1-1, TILE1-2, TILE2-1, and TILE2-2 are outputted to the first to first output ports OUT1 to OUT8. Multiplexers MUX1 to MUX8 are provided.

For example, the output signals of the first and third groups TILE1-1 and TILE2-1 are configured to be output to the first output port OUT1 through the first multiplexer MUX1.

Accordingly, the first to eighth control signals Grant1 of the scheduler 10 are selected so that the output signals are outputted to the first to eighth output ports OUT1 to OUT8 by selecting the first to eighth multiplexers MUX1 to MUX8. The first to fourth output control units 31 to 34 for selecting the first to eighth multiplexers MUX1 to MUX8 by combining <1: 8>: Grant8 <1: 8>. (TILE1-1, TILE1-2, TILE2-1, TILE2-2), respectively.

In this case, as illustrated in FIG. 4, the third output controller 33 corresponds to the third group TILE2-1 for each control signal Grant1 to Grant4 of the scheduler 10 corresponding to the third group TILE2-1. To the fifth to eighth gates OR5 to OR8 for enabling the first to fourth multiplexers MUX1 to MUX4 for receiving the input port selection bits and outputting the output signal of the third group TILE2-1. Is done.

For example, in order to select and output the first output port OUT1 of the third group TILE2-1 by the third output controller 33, the input ports IN5 to IN8 of the first control signal Grant1 are selected. If any one of the bits Grant1 <5>, Grant1 <6>, Grant1 <7>, and Grant1 <8> is output, the output of the fifth gate OR5 is '1'. The first multiplexer MUX1 is enabled to select the first output port OUT1 so that the output signal is output, and the configuration for selecting the second to fourth output ports OUT2 to OUT4 is the same. It consists of.

In addition, the first to fourth output control units 31 to 34 for selecting output ports of the first to fourth groups TILE1-1, TILE1-2, TILE2-1, and TILE2-2 are configured in the above manner. do.

Therefore, assuming that data is to be transferred from the third input port IN3 to the eighth output port OUT8, information to be sent to the eighth output port OUT8 is first displayed on the REQ3 input of the scheduler 10. . The scheduler 10 selects one input port through an internal algorithm among the input ports for which the eighth output port OUT8 is desired.

Herein, when the third input port IN3 is selected, the scheduler loads information for selecting the third input port IN3 to the eighth control signal Grant8 <1: 8> output having 8 bits. That is, only the eighth control signal Grant8 <3> entering the gate of the transistor N38 becomes '1', and the remaining Grant8 <1: 2> and Grant8 <4: 8> are set to '0'.

Then, the third input port IL3-1 of the first group TILE1-1 is disabled through the first input controller 21, and the second group TILE1-2 is controlled through the second input controller 22. Enable the third input port IL3-2 and the third input port IL3-1 of the first group TILE1-1 does not carry data and does not carry the third input of the second group TILE1-2. Data is sent only to port IL3-2.

In addition, the eighth multiplexer MUX8 of the second group TILE1-2 is enabled through the second output controller 32 to output an output signal through the eighth output port OUT8.

Accordingly, the load that the input driver circuit should drive is the wire capacitance of the input horizontal line itself of the second group TILE1-2 and the input width of the second group TILE1-2. The junction capacitances of the four transistors on the line, and the wire capacitances of the output vertical lines of the second group TILE1-2 and the output vertical lines of the second group TILE1-2 With the junction capacitance of the four transistors attached, the junction capacitance of the eight transistors and the wire capacitance of the input / output lines reduce the power required to be charged / discharged by half, reducing power consumption. In addition, the operation speed can be improved.

As described above, the present invention divides the entire crossbar switch into a plurality of small groups, so that only the group whose data is actually switched by the scheduler's control signal is activated by the input signal and the output signal output from each group. By controlling, the driving load is limited to each group, thereby reducing power consumption and improving operating speed.

Claims (3)

In the crossbar switch composed of a crossbar switch arranged vertically and horizontally the input line and the output line and a scheduler for controlling the operation of the crossbar switch, A plurality of groups of crossbar switches arranged vertically and horizontally, An input control unit for combining one of the control signals of the scheduler to select one of the plurality of groups so that an input signal is applied through an input port; A plurality of multiplexers which receive the output signals of the plurality of groups and output them to an output port; An output control unit for selecting one of the multiplexers by combining control signals of the scheduler to output an output signal through the output port Low power crossbar switch, characterized in that consisting of. The method of claim 1, wherein the input control unit An orgate receiving the same input port selection bits in the control signal of the scheduler corresponding to each group; A switch for controlling an input signal by the output signal of the or gate Low power crossbar switch, characterized in that consisting of. The method of claim 1, wherein the output control unit An orgate configured to receive input port selection bits corresponding to each group for each control signal of the scheduler corresponding to each group to enable the multiplexer Low power crossbar switch, characterized in that consisting of.

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