JP4752400B2 - Load drive device and load drive system - Google Patents

Description

  The present invention relates to a load driving device and a load driving system, and more particularly to a load driving device and a load driving system for driving a load.

  In recent years, liquid crystal televisions, mobile phones and the like are rapidly spreading. Since a liquid crystal television and a mobile phone are not self-luminous type, a backlight is mounted on the back surface. Conventionally, a cathode ray tube has been mainly used as a backlight. However, with the development of a white light emitting diode, a white light emitting diode has attracted attention as a backlight. When white light emitting diodes are used as the backlight, it is necessary to arrange and drive a large number of light emitting diodes.

  For this reason, development of a light emitting diode drive IC capable of driving a large number of light emitting diodes has been urgently performed (see Patent Document 1).

  FIG. 12 shows a system configuration diagram of an example of a conventional light emitting diode driving system.

  A conventional light emitting diode driving system 1 includes a driving circuit 11 and light emitting diodes LED1 to LED6. The drive circuit 11 includes a drive IC 21, a drive power supply 22, capacitors C1 to C4, and a resistor R1.

  The drive IC 21 is composed of a one-chip semiconductor chip, and supplies a drive current to the light emitting diodes LED1 to LED6 by a power supply voltage supplied from the drive power supply 22 to cause the light emitting diodes LED1 to LED6 to emit light.

At this time, the drive IC 21 controls the drive currents of the light emitting diodes LED5 and LED6 from the control signal supplied to the port P3, and controls the drive currents of the light emitting diodes LED1 to LED4 from the control signal supplied to the port P4. It had been.
JP 2002-359090 A

  However, in the conventional driver IC, it is necessary to set the drive current of the load by each driver, and when a large number of loads are driven by a plurality of driver ICs, it is difficult to set the drive current of the load.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a load drive device and a load drive system that can easily set drive data with a simple configuration.

  The present invention is a load driving device for driving a load, which is supplied with a clock, driving data, and an input selection signal, detects a clock according to the input selection signal, and reads and reads the driving data according to the detected clock. The drive data (D) is set, the output selection signal is generated according to the detected clock, and the output data is output. The drive data setting circuit (131) that outputs the output selection signal, and the drive data set in the drive data setting circuit (131) And a drive circuit (132) for driving loads (LED11 to LED16, LED21 to LED26, LED31 to LED36) based on (D).

  The drive data (D) includes identification information (d11) for identifying the loads to be driven (LED11 to LED16, LED21 to LED26, LED31 to LED36), and loads (LED11 to LED16, LED21) corresponding to the identification information (d11). ~ LED26, LED31 ~ LED36) and control data (d12) for controlling the drive current, and the drive circuit (132) is a load corresponding to the identification information (d11) set in the drive data setting circuit (131) ( LED11 to LED16, LED21 to LED26, LED31 to LED36) are driven according to corresponding control data (d12).

The present invention is also a load driving apparatus for driving a load, wherein a clock, drive data, and selection pulses are supplied, the number of selection pulses is reduced, and the reduced number of pulses becomes a predetermined number of pulses. A drive data setting unit (231) that reads the drive data, sets the read drive data (D), and outputs a reduced selection pulse when the reduced pulse number is not a predetermined pulse number; And a drive circuit (132) for driving loads (LED11 to LED16, LED21 to LED26, LED31 to LED36) based on the drive data set in the drive data setting unit (231).

  The drive data (D) includes identification information (d11) for identifying the loads to be driven (LED11 to LED16, LED21 to LED26, LED31 to LED36), and loads (LED11 to LED16, LED21 to LED11) corresponding to the identification information (d11). LED26, LED31 to LED36) and control data for controlling the drive current, and the drive circuit (132) is a load (LED11 to LED16, LED21 to LED26) corresponding to the identification information set in the drive data setting unit (231). , LED31 to LED36) are driven according to corresponding control data (d12).

  The load driving system of the present invention is supplied with a clock and driving data and an input selection signal, detects a clock according to the input selection signal, reads the driving data according to the detected clock, sets the read driving data, A drive data setting circuit (131) that generates an output selection signal in accordance with the detection clock and outputs the output selection signal, and a drive circuit that drives the load based on the drive data set in the drive data setting circuit (131) 132) and a load driving system (100) for driving a load by a plurality of load driving devices (112-1 to 112-3), and output selection of the plurality of load driving devices (112-1 to 112-3) A selection signal output port (P17) for outputting a signal and a selection signal input port (P16) for inputting an input selection signal are sequentially connected. ing.

In addition, the load driving system of the present invention is supplied with a clock, driving data, and selection pulses, reduces the number of selection pulses, and when the number of reduced pulses reaches a predetermined number, the driving data (D ), The read drive data (D) is set, and when the reduced number of pulses is not a predetermined number of pulses, a drive data setting unit (231) that outputs a reduced selection pulse, and a drive data setting unit And a drive circuit (132) for driving loads (LED11 to LED16, LED21 to LED26, LED31 to LED36) based on the drive data (D) set in (231). 212-3) is a load driving system (200) that drives the load, and the plurality of load driving devices (212-1 to 212-3) output a selection pulse (P17). Selection pulse output port and (P17) and the selection pulse input port for inputting a selection pulse (P16) is configured to sequentially connect that.

  In addition, the said reference code is a reference to the last, This does not limit a claim.

  According to the present invention, a clock, drive data, and an input selection signal are supplied, the clock is detected according to the input selection signal, the drive data is read according to the detection clock, the read drive data is set, and the detection clock is set. A drive data setting circuit that generates an output selection signal according to the output data and outputs a drive selection signal, and a drive circuit that drives a load based on the drive data set in the drive data setting circuit. Thus, driving data can be set easily.

[First embodiment]
FIG. 1 shows a system configuration diagram of a first embodiment of the present invention.

  The load drive system 100 according to the present embodiment includes a CPU 111 and load drive circuits 112-1 to 112-3, light emitting diodes LED11 to LED16, LED21 to LED26, and LED31 to LED36. In the load drive system 100 of the present embodiment, the brightness of the light emitting diodes LED11 to LED16, LED21 to LED26, and LED31 to LED36 can be dimmed.

  The CPU 111 has first to third ports P1 to P3, outputs a clock CLK from the first port P1, outputs drive data D from the second port P2, and selects from the third port P3. SEL is output. The clock is composed of pulses whose output is inverted at a predetermined cycle. The first to third ports P1 to P3 of the CPU 111 are connected to the load driving circuits 112-1 to 112-3.

  The load driving circuit 112-1 includes a load driving IC 121, a driving power source 122, capacitors C11 to C14, and a resistor R11.

  The load driving IC 121 is composed of a one-chip semiconductor device and has ports P11 to P30. A drive power supply 122 and a capacitor C11 are connected between the power supply port P11 and the ground ports P12 and P13. The capacitor C11 stabilizes the voltage applied from the driving power supply 122 to the port P11.

  The clock input port P14 is connected to the first port P1 of the CPU 111, and the clock CLK is supplied to the port P14 from the first port P1 of the CPU 111. The data input port P15 is connected to the second port P2 of the CPU 111, and drive data is supplied from the CPU 111.

  The selection signal output port P16 is connected to the third port P3 of the CPU 111, and the selection signal SEL is supplied from the third port P3. The selection signal input port P17 is connected to the selection signal input port P16 of the load driving IC 121 constituting the load driving circuit 112-2, and outputs the selection signal SEL of the load driving IC 121 to the selection signal input port P16.

  A shutdown signal is supplied to the shutdown port P18 from an external circuit. The set port P19 is grounded through a resistor R11. By adjusting the resistor R11, the approximate level of the drive current value is set. Further, the drive current is adjusted by the drive data D supplied from the CPU 111.

  The output port P20 is connected to the anodes of the light emitting diodes LED11 to LED16 and one end of the capacitor C14. A predetermined voltage corresponding to the drive current is output from the output port P20. The voltage of the output port P20 is stabilized by the capacitor C14 and applied to the anodes of the light emitting diodes LED11 to LED16.

  The cathode of the light emitting diode LED11 is connected to the control port P21. The brightness of the light emitting diode LED11 is controlled by controlling the current drawn into the control port P21. The cathode of the light emitting diode LED12 is connected to the control port P22. The luminance of the light emitting diode LED12 is controlled by controlling the current drawn into the control port P22.

  The cathode of the light emitting diode LED13 is connected to the control port P23. The brightness of the light emitting diode LED13 is controlled by controlling the current drawn into the control port P23. The cathode of the light emitting diode LED14 is connected to the control port P24. The brightness of the light emitting diode LED14 is controlled by controlling the current drawn into the control port P24.

  The cathode of the light emitting diode LED15 is connected to the control port P25. The luminance of the light emitting diode LED15 is controlled by controlling the current drawn into the control port P25. The cathode of the light emitting diode LED16 is connected to the control port P26. The luminance of the light emitting diode LED16 is controlled by controlling the current drawn into the control port P26.

  A capacitor C12 is connected between the port P27 and the port P28, and a capacitor C13 is connected between the port P29 and the port P30. The delay time and the like are set by the capacitors C12 and C13.

  Next, the main part of the load driving IC 121 will be described.

  FIG. 2 shows a block configuration diagram of a main part of the load driving IC 121.

  The load drive IC 121 includes a drive data setting circuit 131, a drive circuit 132, and a selection signal input circuit 133.

  The drive data setting circuit 131 is supplied with the clock CLK from the port P14 and the drive data D11 to D16 from the port P15, and the selection signal SEL supplied to the port P16 is supplied via the selection signal input circuit 133. The drive data setting circuit 131 detects the clock CLK according to the selection signal SEL, sequentially reads the drive data D11 to D16 according to the detected clock CLK, and corresponds the read drive data D11 to D16 to the ports P21 to P26. And set. Further, the drive data setting circuit 131 generates a selection signal SEL according to the detected clock CLK, and supplies the selection signal SEL to the port P17 and the selection signal input circuit 133.

  Further, the port P16 is connected to the drive data setting circuit 131. When the port P16 becomes low level, the drive data setting circuit 131 resets the port P17 to low level.

  The drive data D set in the drive data setting circuit 131 is supplied to the drive circuit 132.

  The drive circuit 132 drives so as to draw currents corresponding to the drive data set in the drive data D11 to D16 set in the drive data setting circuit 131 from the ports P21 to P26.

  The selection signal input circuit 133 is composed of an AND gate, and an input selection signal is supplied from the port P16 and an inverted signal of the output selection signal generated by the drive data setting circuit 131 is supplied.

  The selection signal input circuit 133 outputs an AND logic of the input selection signal and the inverted signal of the output selection signal. The output of the selection signal input circuit 133 is supplied to the drive data setting circuit 131. When the output of the selection signal input circuit 133 is at a high level, the drive data setting circuit 131 takes in the drive data supplied to the port P15 and sets it inside.

  FIG. 3 is a diagram for explaining the operation of the load driving IC 121.

  The load drive IC 121 can set the drive data D supplied to the port P15 in a state where the port P16 is at a high level and the port P17 is at a low level. The load driving IC 121 is set when the ports P16 and P17 are both at the low level, the port P16 is at the low level, the port P17 is at the high level, and the ports P16 and P17 are both at the high level. The drive data D being held is maintained.

  FIG. 4 shows the data structure of the drive data D.

  The drive data D is composed of a 4-bit ID part d11 and a data part d12.

  The ID part d11 is data for identifying a port for setting drive data set in the data part d12.

  The drive data setting circuit 131 detects the ID part d11 of the drive data D, recognizes the port where the drive data set in the data part d12 is to be set, and is set in the data part d12 corresponding to the recognized port. Set the drive data.

  When the drive data D is set, the drive data setting circuit 131 sets the port P17 to the high level. When the port P17 becomes high level, the output of the selection signal input circuit 133 becomes low level. The drive data setting circuit 131 stops capturing the drive data D when the output of the selection signal input circuit 133 becomes low level.

[Operation]
5 and 6 are diagrams for explaining the operation of the load drive system 100 when setting drive data. 5A shows a clock supplied to the port P14 of the load driving IC 121, FIG. 5B shows data supplied to the port P15 of the load driving IC 121, and FIG. 5C shows the load driving circuit 112-1. 5D shows the state of the port P16 of the load driving IC 121, FIG. 5D shows the state of the port P17 of the load driving IC 121 constituting the load driving circuit 112-1, and FIG. 5E shows the load constituting the load driving circuit 112-2. The state of the port P16 of the driving IC 121, FIG. 5F shows the state of the port P17 of the load driving IC 121 constituting the load driving circuit 112-2, and FIG. 5G shows the load driving IC 121 constituting the load driving circuit 112-3. 5 (H) shows the state of the port P17 of the load drive IC 121 constituting the load drive circuit 112-3, and FIG. 5 (I) shows the state of the drive data.

  When setting the drive data, the CPU 111 first sets the port P3 to the high level at time t11 and supplies the drive data D11 to the load drive circuits 112-1 to 112-3. When the port P3 of the CPU 111 becomes high level, the port P16 of the load driving IC 121 constituting the load driving circuit 112-1 becomes high level as shown in FIG. 5C. At this time, since the port P17 of the load driving IC 121 constituting the load driving circuit 112-1 is at a low level as shown in FIG. 5D, the selection signal input of the load driving IC 121 constituting the load driving circuit 112-1 is input. The output of the circuit 133 becomes high level. As a result, as shown in FIG. 6A, the port P16 of the load driving IC 121 constituting the load driving circuit 112-1 becomes high level, and the port P17 becomes low level.

  Accordingly, the drive data setting circuit 131 takes in the drive data D11 supplied from the CPU 111. By the ID part d11 of the drive data D11, the port P21 is recognized as a port for which drive data is to be set. The drive data setting circuit 131 sets the data set in the data part d12 as data to drive the port P21 based on the recognition result. Similarly, data corresponding to ports P22 to P26 are sequentially set at times t12 to t21.

  When the drive data setting circuit 131 finishes capturing the drive data D11 to D16 at time t21, the port P17 is set to the high level as shown in FIG. When the port P17 becomes high level, the output of the selection signal input circuit 133 becomes low level, and the drive data setting circuit 131 constituting the load drive circuit 112-1 stops taking in drive data.

  When the port P17 of the load drive IC 121 constituting the load drive circuit 112-1 becomes high level at time t21, the port P16 of the load drive IC 121 constituting the load drive circuit 112-2 is high as shown in FIG. Become a level. At this time, since the port P17 of the load driving IC 121 constituting the load driving circuit 112-2 is at a low level as shown in FIG. 5F, the load driving circuit 112-2 is turned on as shown in FIG. The port P16 of the load driving IC 121 to be configured is at a high level, and the port P17 is at a low level. As a result, the output of the selection signal input circuit 133 becomes high level, and the drive data setting circuit 131 starts taking in the drive data D21 supplied from the CPU 111. When the drive data setting circuit 131 finishes taking in the drive data D21 from time t21 to t31, the port P17 of the load drive IC 121 is set to high level at time t31. When the port P17 becomes high level, the output of the selection signal input circuit 133 becomes low level, and the drive data setting circuit 131 constituting the load drive circuit 112-2 stops capturing drive data.

  Further, when the port P17 of the load driving IC 121 constituting the load driving circuit 112-2 becomes high level as shown in FIG. 5F at time t31, the port P16 of the load driving IC 121 constituting the load driving circuit 112-3. Becomes a high level as shown in FIG. At this time, since the port P17 of the load driving IC 121 constituting the load driving circuit 112-3 is at a low level, the load driving IC 121 constituting the load driving circuit 112-3 is connected to the port P16 as shown in FIG. Becomes high level and the port P17 becomes low level, the output of the selection signal input circuit 133 becomes high level.

  When the output of the selection signal input circuit 133 becomes high level, the drive data setting circuit 131 constituting the load drive circuit 112-3 starts taking in drive data D31 supplied from the CPU 111. The drive data setting circuit 131 sets the port P17 to high level when the drive data capture is completed. When the port P17 becomes high level, both the ports P16 and P17 become high level. Therefore, the output of the selection signal input circuit 133 becomes low level, and the drive data setting circuit 131 constituting the load drive circuit 112-3 receives the drive data. Stop capturing.

  When the CPU 111 finishes fetching drive data into the load drive IC 121 of the load drive circuits 112-1 to 112-3, the CPU 111 sets the port P 3 to low level. When the port P3 of the load driving IC 121 constituting the load driving circuit 112-1 is set to the low level due to the port P3 becoming the low level, the drive data setting circuit 131 of the load driving IC 121 resets the port P17 to the low level. To do.

  When the port P17 of the load driving IC 121 constituting the load driving circuit 112-1 is reset to the low level, the port P16 of the load driving IC 121 constituting the load driving circuit 112-2 is set to the low level. When the port P16 of the load drive IC 121 constituting the load drive circuit 112-2 is set to the low level, the drive data setting circuit 131 of the load drive IC 121 resets the port P17 to the low level.

  When the port P17 of the load driving IC 121 constituting the load driving circuit 112-2 is reset to the low level, the port P16 of the load driving IC 121 constituting the load driving circuit 112-3 is set to the low level. When the port P16 of the load driving IC 121 constituting the load driving circuit 112-3 is set to the low level, the driving data setting circuit 131 of the load driving IC 121 resets the port P17 to the low level.

  As described above, as shown in FIG. 6D, the ports P16 and P17 of the load driving IC 121 constituting the load driving circuits 112-1 to 112-3 are set to the low level. As a result, the drive data can be set again in the load drive IC 121 constituting the load drive circuits 112-1 to 112-3 by the CPU 111.

  The current drawn from each port P21 to P26, that is, the load current can be set by the above operation. Therefore, the currents flowing through the plurality of light emitting diodes LED11 to LED16, LED21 to LED26, and LED31 to LED36 connected to the plurality of load driving ICs 121 can be individually set.

[Second Embodiment]
FIG. 7 shows a block diagram of a second embodiment of the present invention. In the figure, the same components as in FIG.

  The load drive system 200 of the present embodiment is different from the first embodiment in the configuration of the load drive circuits 212-1 to 212-3. The load drive circuits 212-1 to 212-3 of this embodiment are different from the first embodiment in the configuration of the load drive IC 221.

  FIG. 8 is a block diagram of the load driving IC 221, and FIG. 9 is an operation explanatory diagram of the load driving IC 221. In the figure, the same components as in FIG.

  The load drive IC 221 includes a drive data setting unit 231 and a drive circuit 132.

  When the number of input pulses supplied to the port P16 becomes “1”, the drive data setting unit 231 sets the drive data supplied from the port P3 of the CPU 111 at that time. Further, as shown in FIG. 9, when the pulse supplied to the port P16 is larger than “1”, the drive data setting unit 231 is a pulse obtained by thinning the number of pulses from “3” of the input pulse pin by “1”. The output pulse pout of the number “2” is output from the port P17.

  FIG. 10 shows a process flowchart of the drive data setting unit 231.

  When a pulse is input to the port P16 in step S1-1, the drive data setting unit 231 cancels the first pulse of the input pulse in step S1-2. As a result, the number of pulses is “−1”.

  The drive data setting unit 231 determines whether or not the pulse number after the pulse number is “−1” in step S1-3 is “0”. If it is determined in step S1-3 that the number of pulses is “0”, the drive data setting unit 231 takes in the drive data supplied to the port P15 at that time in step S1-4, and outputs the corresponding port. Set as drive data of P21 to P26.

  Next, in step 1-5, the drive data setting unit 231 sends out the pulse whose number of pulses is “−1” in step S1-2 from the port P17.

  If the number of pulses is not “0” in step S1-3, the drive data setting unit 231 maintains the drive data state in step S1-6, and in step S1-5, step S1-2. Then, a pulse with the number of pulses set to "-1" is transmitted from the port P17.

  The drive data setting unit 231 sets drive data by the above processing.

  FIG. 11 is an operation explanatory diagram of the load driving system 200. FIG. 11A shows the pulse state of the load drive circuits 212-1 to 212-3 at time t1, and FIG. 11B shows each load drive when the load drive circuits 212-1 to 212-3 are set at time t2. FIG. 11C shows the state of data in the circuits 212-1 to 212-3. FIG. 11C shows the state of pulses in the load driving circuits 212-1 to 212-3 when the load driving circuit 212-2 is set. D) is the state of data in each of the load drive circuits 212-1 to 212-3 when the load drive circuit 212-2 is set, and FIG. 11E is each load drive circuit when the load drive circuit 212-1 is set. FIG. 11F shows the state of pulses in 212-1 to 212-3, and the state of data in each load drive circuit 212-1 to 212-3 when the load drive circuit 212-1 is set.

  When the drive data D3 is set in the load drive circuit 212-3, the CPU 111 continues three pulses at the port P16 of the load drive IC 221 constituting the load drive circuit 212-1 as shown in FIG. The drive data D3 to be set in the load drive circuit 212-3 as drive data is output from the port P2 as shown in FIG. 11B.

  The number of pulses of the pulse output from the port P3 of the CPU 111 is “−1” in the load driving circuit 212-1 and the load driving circuit 212-2, and the load driving IC 221 constituting the load driving circuit 212-3 The port P16 is supplied with a pulse whose number of pulses is “1”.

  As a result, the drive data D3 is set in the load drive IC 221 constituting the load drive circuit 212-3.

  Further, when the drive data D2 is set in the load drive circuit 212-2, the CPU 111 sets two pulses at the port P16 of the load drive IC 221 constituting the load drive circuit 212-1 as shown in FIG. Are input, and driving data D2 to be set in the load driving circuit 212-2 is output from the port P2 as driving data as shown in FIG.

  The pulse number output from the port P3 of the CPU 111 is "-1" in the load driving circuit 212-1 and the pulse number is "1" in the port P16 of the load driving IC 221 constituting the load driving circuit 212-2. Are supplied. As a result, the drive data D2 is set in the load drive IC 221 constituting the load drive circuit 212-2.

  Further, when setting the drive data D1 in the load drive circuit 212-1, the CPU 111 has a pulse number at the port P16 of the load drive IC 221 constituting the load drive circuit 212-1 as shown in FIG. A pulse “1” is input, and drive data D1 to be set in the load drive circuit 212-1 as drive data is output from the port P2 as shown in FIG.

  The pulse having the number of pulses “1” output from the port P3 of the CPU 111 is supplied to the port P16 of the load driving IC 221 constituting the load driving circuit 212-1. As a result, the drive data D1 is set in the load drive IC 221 constituting the load drive circuit 212-1.

  According to this embodiment, by setting the number of pulses by the CPU 111, driving to a desired load driving IC 221 without resetting the driving data of the load driving ICs 221 of all the load driving circuits 212-1 to 212-3. Only the data can be reset.

[Others]
In this embodiment, the configuration in which the three load drive circuits 112-1 to 112-3 are connected has been described. However, a single drive is possible, and two or more load drive circuits are connected. It is also possible to control the current of the load connected to each load driving circuit.

  In this embodiment, the light emitting diode is described as an example of the load. However, the present invention is not limited to this, and it is needless to say that the present invention can also be applied to a load driving circuit for setting a driving current of another load.

It is a system configuration figure of the 1st example of the present invention. 3 is a block configuration diagram of a main part of a load driving IC 121. FIG. 6 is an operation explanatory diagram of a load driving IC 121. FIG. 4 is a data configuration diagram of drive data D. FIG. FIG. 4 is an operation explanatory diagram when setting drive data of the load drive system 100; FIG. 4 is an operation explanatory diagram when setting drive data of the load drive system 100; It is a block block diagram of 2nd Example of this invention. 2 is a block configuration diagram of a load driving IC 221. FIG. 6 is an operation explanatory diagram of a load driving IC 221. FIG. 5 is a process flowchart of a drive data setting unit 231. 6 is an operation explanatory diagram of the load driving system 200. FIG. It is a system block diagram of an example of the conventional light emitting diode drive system.

Explanation of symbols

100, 200 Load drive system 111 CPU, 112-1 to 112-3, 212-1 to 212-3 Load drive circuit 121, 221 Load drive IC
LED11 to LED16, LED21 to LED26, LED31 to LED36 Light emitting diode

Claims (6)

A load driving device for driving a load,
A clock, drive data, and an input selection signal are supplied, the clock is detected according to the input selection signal, the drive data is read according to the detection clock, the read drive data is set, and the detected clock is set A drive data setting circuit that generates an output selection signal in response to the output selection signal and outputs the output selection signal;
And a drive circuit that drives the load based on the drive data set in the drive data setting circuit. The drive data includes identification information for identifying a load to be driven, and control data for controlling a drive current of a load corresponding to the identification information.
2. The load drive circuit according to claim 1, wherein the drive circuit drives a load corresponding to the identification information set in the drive data setting circuit in accordance with the corresponding control data. A load driving device for driving a load,
Clock and drive data and selection pulse are supplied, the number of pulses of the selection pulse is reduced, and when the reduced number of pulses reaches a predetermined number of pulses, the drive data is read and the read drive data is set When the reduced number of pulses is not a predetermined number of pulses, a drive data setting unit that outputs a reduced selection pulse;
And a drive circuit that drives the load based on the drive data set in the drive data setting unit. The drive data includes identification information for identifying a load to be driven, and control data for controlling a drive current of a load corresponding to the identification information.
4. The load drive circuit according to claim 3, wherein the drive circuit drives a load corresponding to the identification information set in the drive data setting unit in accordance with the corresponding control data. A clock, drive data, and an input selection signal are supplied, the clock is detected according to the input selection signal, the drive data is read according to the detection clock, the read drive data is set, and the detected clock is set A plurality of loads having a drive data setting circuit that generates an output selection signal in response to the output data and outputs the output selection signal; and a drive circuit that drives the load based on the drive data set in the drive data setting circuit A load driving system for driving a load by a driving device,
In the plurality of load driving devices, a selection signal output port for outputting the selection signal and a selection signal input port for inputting the selection signal are sequentially connected. Clock and drive data and selection pulse are supplied, the number of pulses of the selection pulse is reduced, and when the reduced number of pulses reaches a predetermined number of pulses, the drive data is read and the read drive data is set When the reduced number of pulses is not a predetermined number, the driving data setting unit that outputs the reduced selection pulse and the load are driven based on the driving data set in the driving data setting unit. A load driving system that drives a load by a plurality of load driving devices having a driving circuit,
In the plurality of load driving devices, a selection pulse output port for outputting the selection pulse and a selection pulse input port for inputting the selection pulse are sequentially connected.

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