JPH1058739A - Circuit for driving light-emitting element array - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light-generating element array-driving circuit which enables an image-recording apparatus to operate with high resolution at high speed. SOLUTION: A laser array-driving circuit driving an array of lasers arranged in two dimensions is provided with a plurality of column drive circuits 4 for driving lasers 1 arranged in a column direction, a plurality of row drive circuit 5 for driving lasers 1 arranged in a row direction, and control circuits 6, 7. The control circuit 6, 7 sequentially carries out a control operation to all of a plurality of lasers 1 constituting the laser array. More specifically, in the control operation, one laser among the plurality of lasers 1 is turned ON by operating the column drive circuit 4 and row drive circuit 5 related to the laser simultaneously in accordance with input data, or turned OFF by prohibiting the corresponding row drive circuit 5 from driving. Each row drive circuit 5 is provided with drivers 51, 52 which alternately act to drive lasers at columns of odd numbers and even numbers, and a driving value-setting circuit 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light emitting element array driving circuit in an image recording apparatus such as a copying machine or a printer using a light emitting element array having a plurality of independently controllable light emitting elements.

[0002]

2. Description of the Related Art In recent years, the required level of image quality of an image recording apparatus such as a copying machine or a printer of an electrophotographic system has been increased, and the precision of a printed image, that is, the resolution has been increased.
And speeding up. As a conventional image recording apparatus, a laser beam scanning apparatus using a polygon mirror or L
An image recording apparatus using an image bar such as an ED array is widely used. Various proposals have also been made on a method of driving a laser or an LED serving as a light emitting element of these image recording apparatuses. When an array is formed using these light-emitting elements, variations in the amount of light between the individual light-emitting elements are unavoidable. A drive circuit incorporating a correction circuit has been proposed. For example, Japanese Patent Application Laid-Open Nos. 62-273863 and 63-27162 detect the light emission amount of each light emitting element of a light emitting element array including a plurality of light emitting elements.
Based on the detected signal, a method of obtaining a digital signal in which the light amount variation of each light emitting element is corrected by using data of a counter or a memory using a data of a counter, and converting the digital signal into a DA value to set a current value to be applied to the light emitting element. Is disclosed.

On the other hand, as a new image recording apparatus, there has been proposed an image recording apparatus using a laser array or an LED array as a light source in which surface emitting semiconductor lasers are two-dimensionally arranged. These light-emitting elements have higher luminous intensity than fluorescent display tubes and the like. In addition, by arranging the light-emitting elements two-dimensionally, it is possible to integrate the light-emitting spots at a high density, thereby further improving the resolution. This is effective in increasing the speed. In order to integrate such two-dimensionally arranged light emitting elements at a high density, it is common to use a matrix wiring due to the wiring area. There is also an effect that the number of drive circuits can be reduced by using the matrix wiring. In other words, the number of drive circuits can be greatly increased by adopting a drive method in which, for example, a drive circuit for sequentially driving a plurality of light-emitting elements arranged in a row direction is provided for each row without providing a drive circuit for each light-emitting element. Can be reduced.

[0004]

However, when the above-described driving method is adopted, in order to correct the variation in the light amount of each light emitting element, the driving current value of the light emitting element must be set sequentially for each light emitting element. In addition, there is a problem that the setting time of the drive current value hinders an increase in the resolution and speed of the image recording apparatus. Hereinafter, this problem will be described with reference to the drawings.

FIG. 7 is a circuit diagram of a conventional laser array drive circuit. FIG. 7 shows a laser array driving circuit for driving a laser array composed of lasers 1 (m, n) (m = 1 to M, n = 1 to N) two-dimensionally arranged in M rows and N columns. ing. The laser array driving circuit includes a first driving circuit group 4 including N column driving circuits 4 (n) (n = 1 to N), and M row driving circuits 5 (m) (m = 1 To M), a control circuit 6 for controlling the first drive circuit group 4, a control circuit 7 for controlling the second drive circuit group 5, and each laser 1 (m, n) (m = 1 to M, n = 1
To N) and each column drive circuit 4 (n) (n = 1 to
N), and a column common line 2 (n) (n = 1 to N),
A row common line 3 (m) (m) connecting the cathode of each laser 1 (m, n) (m = 1 to M, n = 1 to N) and each row drive circuit 5 (m) (m = 1 to M) m = 1 to M) and a drive value setting circuit 10 (m) for setting a drive value for driving the laser.
(M = 1 to M). Each row drive circuit 5
(M) (m = 1 to M) includes a driver for supplying a drive current corresponding to the input drive current value to each of the corresponding lasers 1 (m, n).

In the following description, for the sake of simplicity, the range of a subscript m indicating a row number and the range of a subscript n indicating a column number are shown (m = 1 to M) and (n = 1 to 1).
The notation of N) is omitted. The control circuit 6 and the control circuit 7
Regarding one of a plurality of lasers constituting a laser array, a column driving circuit 4 (n) and a row driving circuit 5 (m) corresponding to the laser are changed according to input data corresponding to the laser. The operation of controlling whether the laser is turned on by simultaneously acting on the laser, or whether the row driving circuit 5 (m) corresponding to the laser is kept in the light-off state by inhibiting the action on the laser, The process is sequentially performed on a plurality of lasers constituting a laser array. More specifically, the control circuit 6 that performs control in the column direction includes, for example, a shift register circuit, and sequentially turns on / off the column drive circuit 4 (n) at a predetermined cycle. The control circuit 7 for controlling the row direction turns ON / OFF the driving operation for driving the laser according to the input data by the row driving circuit 5 (m).
OFF control. By doing so, for example, when both the column drive circuit 4 (1) and the row drive circuit 5 (1) are turned on, the drive current output from the row drive circuit 5 (1) is applied to the laser 1 (1,1). ), And the laser 1 (1, 1) emits light.

As described above, since the light amounts of the individual lasers vary, it is necessary to correct the light amounts of the individual lasers constituting the laser array. Therefore, the light amount of each laser is measured in advance, and drive value setting data based on the measured data is stored in the memory of the laser array driving device,
At the stage of driving the laser array, the drive value setting data is read out, and the drive current of each laser is set based on the data. Now, assuming that the first row of the laser array is selected, the address of the memory 8 (1) is counted up by a control circuit such as a counter (not shown), and the drive value setting data corresponding to the laser in the first row is obtained. Read sequentially. The read drive value setting data is stored in the DA converter 9.
Input to (1). In the DA converter 9 (1), a drive value to be supplied to the row drive circuit 5 (1) is set based on the read drive value setting data. The row drive circuit 5 (1) supplies a drive current based on the drive value to a predetermined laser. When the supply of the drive current to the laser in the first row by the row drive circuit 5 (1) is completed, the operation shifts to the laser drive in the second row. The same operation as that of the first row is performed for the second and subsequent rows, and the two-dimensionally arranged lasers 1 (m, n) are sequentially driven.

The current is supplied from each column drive circuit 4 (n) to each laser, and the current value supplied from each column drive circuit 4 (n) is supplied from each row drive circuit 5 (m). Is set to a current value larger than the maximum value of the current
The drive current actually flowing through the laser is the row drive circuit 5 (m).
Is determined by the magnitude of the current supplied from the However, in the laser array drive circuit configured as described above, as described below, the time required for setting the drive value of each laser is limited, and it is difficult to increase the resolution and speed of the image recording apparatus. There is a problem.

FIG. 8 is an explanatory diagram of the operation time of the laser array drive circuit. When a certain row of the two-dimensionally arranged laser array, for example, the m-th row is selected, the row driving circuit 5
When a certain column, for example, the (n-1) th column is selected and the column drive circuit 4 (n-1) is turned on while (m) is ON, the m-th row (n- 1) row of lasers 1
(M, n-1) the application of the drive current to is started, after a predetermined laser drive time t ₁ has elapsed, then the current application is complete, the m follows laser of the n column 1 (m, n) Is started. This drive value setting is performed in the memory 8 as described above.
A process of reading out the n-th drive value setting data from the drive value setting data of the N lasers in the m-th row stored in (m), and performing row driving based on the read out drive value setting data. The drive value supplied to the circuit 5 (m) is
(M) includes a setting process, and a considerable processing time is required.

By the way, the control circuit 6, a printer or on the basis of column selection control signal period t ₃ when determined from the main scanning direction of the pixel pitch in a copying machine column driver circuit 4 (n) O
N / OFF control is performed, but a drive value setting time t ₂ obtained by subtracting the laser drive time t ₁ from the column selection control signal period t _3.
Within that time, the setting of the drive value of the laser to be turned on next must be completed.

On the other hand, if the pixel pitch is narrowed to increase the resolution of the image recording apparatus, the column selection control signal period t ₃
Is shortened by that amount, and even if the pixel pitch is the same, if the process speed (the rotation speed of the drum) is increased, the scanning time for one line in the main scanning direction is shortened. The period t ₃ also becomes shorter. That is, resolution of the image recording apparatus, in order to increase the speed, it is necessary to shorten the drive value set time t _2. However, it is extremely difficult to shorten the drive value setting time t ₂ in the conventional light emitting element array drive circuit, and the drive value setting time t ₂ is a factor that hinders high resolution and high speed.

In view of the above circumstances, it is an object of the present invention to provide a light emitting element array driving circuit capable of increasing the resolution and speed of an image recording apparatus.

[0013]

A light emitting element array driving circuit according to the present invention for achieving the above object drives a light emitting element array comprising a plurality of light emitting elements arranged two-dimensionally in a row direction and a column direction. In the light emitting element array driving circuit, a plurality of first driving circuits provided corresponding to each column in which the plurality of light emitting elements constituting the light emitting element array are arranged and driving the plurality of light emitting elements arranged in the corresponding column The first consisting of
And a plurality of second drive circuits provided corresponding to each row in which the plurality of light emitting elements constituting the light emitting element array are arranged and driving the plurality of light emitting elements arranged in the corresponding row. A second driving circuit group and, for one of the plurality of light emitting elements constituting the light emitting element array, a first drive corresponding to the light emitting element according to input data corresponding to the light emitting element; The light emitting element is turned on by simultaneously operating the circuit and the second driving circuit on the light emitting element, or at least one of the first driving circuit and the second driving circuit corresponding to the light emitting element is driven. A control circuit for sequentially executing the operation of controlling whether to maintain the light emitting element in the light-off state by inhibiting the action on the light emitting element for the plurality of light emitting elements constituting the light emitting element array And a plurality of drive circuits constituting at least one drive circuit group of the first drive circuit group and the second drive circuit group act alternately and correspond to the input drive value. A plurality of drivers for supplying a drive current or a drive voltage to the light emitting element, and a drive value setting circuit for supplying the drive value to the plurality of drivers are provided.

Here, the drive value setting circuit is provided in common with the plurality of drivers, the memory storing the drive values, and the drive value setting circuit is provided for each of the plurality of drivers. A latch for temporarily storing the drive value read from the memory, and a DA converter for converting a digital signal representing the drive value stored in the latch into an analog signal and supplying the analog signal to a corresponding driver. Preferably, it is provided.

In addition, each of the plurality of drive circuits constituting the one drive circuit group may include, in addition to the plurality of drivers,
The action on the light emitting element or the inhibition of the action is controlled simultaneously with the plurality of drivers according to the input data. A predetermined driving current or a predetermined driving current is supplied to the light emitting element regardless of the drive value supplied from the drive value setting circuit. A driver that supplies a voltage may be provided. Alternatively, each of the plurality of driver circuits included in the one driver circuit group may act on the light emitting element irrespective of input data in addition to the plurality of drivers. Further, a driver that supplies a predetermined drive current or drive voltage to the light emitting element regardless of the drive value supplied from the drive value setting circuit may be provided.

[0016]

Embodiments of the present invention will be described below. FIG. 1 is a circuit diagram showing a first embodiment in which the light emitting element array drive circuit of the present invention is applied to a laser array. As shown in FIG. 1, this laser array drive circuit has the same configuration as the conventional laser array drive circuit shown in FIG.
Column common line 2 (n), row common line 3 (m), column drive circuit 4 (n), row drive circuit 5 (m), control circuits 6, 7
And a drive value setting circuit 10 (m). Since these components are the same as those in the conventional example shown in FIG. 7, the description will be omitted, and only the differences will be described below.

The difference between the laser array drive circuit of the present embodiment and the conventional laser array drive circuit is that (1) a drive current corresponding to the input drive value is assigned to each row drive circuit 5 (m). A first driver 51 (m) and a second driver 52 (m) for supplying each of the lasers 1 (m, n) to be driven, and (2) each drive value setting circuit 10 (m) Is provided with a first memory 81 (m), a first DA converter 91 (m), a second memory 82 (m), and a second DA converter 92 (m). . Hereinafter, these differences will be described.

The drive current to each laser 1 (m, n) is supplied to a first driver 51 (m) and a second driver 52 (m) provided in the row drive circuit 5 (m) and acting alternately. Supplied by That is, when an odd-numbered row is selected by the control circuit 7, the first driver 51 (m) supplies a drive current to a laser corresponding to the odd-numbered row to emit light, and
When an even-numbered row is selected by the control circuit 7, the second driver 52 (m) supplies a drive current to a laser corresponding to the even-numbered row to emit light. First driver 51
(M) and a drive value on which the drive current of the second driver 52 (m) is based is supplied from the drive value setting circuit 10 (m).

The first memory 81 (m) provided in the drive value setting circuit 10 (m) stores drive value setting data corresponding to the odd-numbered column lasers in each row. In the memory 82 (m), drive value setting data corresponding to the even-numbered column laser in each row is stored. The drive value setting circuit 10 (m) thus configured
However, the setting of the drive values from the first row to the M-th row based on the control from the control circuit 7 is alternately executed by the two drive lines for the odd-numbered column laser and the even-numbered column laser.
For example, the drive value setting of the laser 1 (1, 1) in the first row and first column is performed as follows. First, the first memory 81
The address of (1) is counted up, and the drive value setting data corresponding to the laser 1 (1, 1) arranged in the first column is read. The first DA converter 91 (1) sets a drive value based on the read drive value setting data and supplies it to the first driver 51 (1). First driver 5
1 (1) supplies a drive current corresponding to the received drive value to the laser 1 (1,1). Next, the drive values of the lasers 1 (1, 2) in the first row and second column are set. First, the second
The address of the memory 82 (1) is counted up, and the drive value setting data corresponding to the laser 1 (1, 2) arranged in the second column is read. Second DA converter 92 (1)
Sets a drive value based on the read drive value setting data, and supplies the drive value to the second driver 52 (1). The second driver 52 (1) supplies a drive current corresponding to the received drive value to the laser 1 (1,2). As described above, laser drive is alternately performed by two drive lines for the odd-numbered row laser and the even-numbered row laser.

Since the present embodiment is configured as described above, the drive value setting time can be greatly extended. FIG. 2 is an explanatory diagram of the operation time of the first embodiment of the light emitting element array drive circuit of the present invention. As described above, the light emitting element array drive circuit of the present embodiment is provided with two drive lines for the odd-row laser and the even-row laser, and the two drive lines alternately drive the laser. Therefore, as shown in FIG. 2, the laser driving time t ₁
And the total time of the drive values set time t ₂ is, so that it Osamare within two cycles of time column selection control signal period t _3. As described above, the conventional light emitting element array driving circuit (FIG. 8)
Compared to the reference), a large margin in the drive value set time t ₂ occurs, significantly higher resolution it is possible to shorten the column selection control signal period t _3, it is possible to realize high-speed.

Next, a description will be given of a second embodiment of the light emitting element array drive circuit according to the present invention. FIG. 3 is a circuit diagram showing a light emitting element array drive circuit according to a second embodiment of the present invention. As shown in FIG. 3, the light emitting element array drive circuit of the second embodiment is similar to the first embodiment shown in FIG. 1, and only the configuration of each drive value setting circuit 10 (m) is different. Therefore, the difference will be described below.

In the second embodiment, each drive value setting circuit 1
0 (m) is one memory 8 (m) and the first latch 11 (m) and the second latch 12
(M), a first DA converter 91 (m) and a second DA converter 92 to which outputs from the respective latches are input.
(M). First DA converter 91 (m)
Is input to the first driver 51 (m), and the output of the second DA converter 92 (m) is input to the second driver 52 (m).
(M). First latch 11 (m), first DA converter 91 (m), and first driver 51 (m)
Forming a first drive line for the odd-numbered row laser,
Second latch 12 (m), second DA converter 92
(M) and the second driver 52 (m) form a second drive line for the even-numbered row laser.

The memory 8 (m) stores drive value setting data for each laser in each row. Memory 8
The drive value setting data stored in (m) alternates between a first latch 11 (m) that holds data for odd-numbered row lasers and a second latch 12 (m) that holds data for even-numbered row lasers. And the first DA converter 91 (m) and the second DA converter 91 (m)
Is transferred to the DA converter 92 (m). The first DA converter 91 (m) and the second DA converter 92 (m) each include a first driver 5 for driving an odd-numbered row laser.
The drive current of 1 (m) and the drive current of the second driver 52 (m) for driving the even-numbered row laser are set.

The second embodiment eliminates the need for providing two sets of memories, one for the odd-numbered row lasers and the other for the even-numbered row lasers, so that the memory control circuit can be downsized. Next, a third embodiment of the light emitting element array drive circuit of the present invention will be described. FIG. 4 is a circuit diagram showing a third embodiment of the light emitting element array drive circuit according to the present invention.

As shown in FIG. 4, the light emitting element array drive circuit of the third embodiment is similar to the first embodiment shown in FIG. 1, and only the configuration of each row drive circuit 5 (m) is different. Therefore, the differences will be described below. Third
In the embodiment, each row drive circuit 5 (m) includes an auxiliary driver 53 in addition to the first driver 51 (m) for odd-numbered column lasers and the second driver 52 (m) for even-numbered column lasers.
(M) is provided. This auxiliary driver 53 (m)
Supplies a constant drive current to each laser in the row based on a control signal from the control circuit 7 irrespective of the drive value supplied from the drive value setting circuit 10 (m). The drive values supplied from the auxiliary driver 53 (m) are all constant regardless of the odd-row laser and the even-row laser.

Therefore, the driving current supplied to each laser
Is the current I by the auxiliary driver 53 (m)._o And the first
Current I by driver 51 (m)₁ Or the second dora
Current I by the iva 52 (m)_Two With either one of
Is the sum of FIG. 5 shows the relationship between the laser drive current and the amount of light.
It is a graph which shows a relationship. Drive current of the laser shown in FIG.
In the light amount characteristic curve, the auxiliary driver 53 (m)
Current value I_o To the current level shown in the figure.
The current controlled by the memory or DA converter
I_v Set within. Therefore, the drive supplied to each laser
The dynamic current is the current I by the auxiliary driver 53 (m)._o When,
The current I by the first driver 51 (m)₁ Or the second
Current I by the driver 52 (m) _Two With any of
It is a total value.

[0027] Thus, the auxiliary driver 53 (m) keep biased current I _o fraction by, by and configured to apply current I ₁ or I ₂ differences thereon, the third embodiment In the case where the current supplied to the laser is controlled with the same resolution as in the first embodiment, the control range is greatly narrowed, so that the amount of drive value setting data stored in the memory can be reduced, and the DA converter Accuracy can be reduced.

Next, a fourth embodiment of the light emitting element array driving circuit according to the present invention will be described. FIG. 6 is a circuit diagram showing a fourth embodiment of the light emitting element array drive circuit according to the present invention. As shown in FIG. 6, the light emitting element array drive circuit of the fourth embodiment is similar to the third embodiment shown in FIG. 4, and only the configuration of each row drive circuit 5 (m) is different. Therefore, the difference will be described below.

In the fourth embodiment, each row driving circuit 5
(M) shows a first driver 51 for an odd-numbered row laser.
(M), a second driver 52 (m) for the even-row laser,
A second auxiliary driver 54 (m) is provided in addition to the first auxiliary driver 53 (m). The second auxiliary driver 54 (m) supplies a constant current I _th (see FIG. 5) irrespective of the drive value supplied from the drive value setting circuit 10 (m) and independently of the control circuit 7. The laser is supplied to each of the m rows. Also, the first auxiliary driver 53 (m)
Is a constant current I based on a control signal from the control circuit 7.
₀ ′ (see FIG. 5) is supplied to each laser in the m-th row.

Therefore, the driving current supplied to each laser is the current I _th by the second auxiliary driver 54 (m),
A current I _o 'of the first sub-driver 53 (m), the sum of either one of the current I ₂ of the first driver 51 (m) current I ₁ or the second driver 52 by (m) Value. Here, the second auxiliary driver 54
If the current I _th by (m) is set to a current value just before the laser starts to emit light in the drive current-light amount characteristic curve as shown in FIG. 5, the response speed of the laser itself increases, and the speed is further increased. Can be achieved.

In each of the above-described embodiments, the plurality of drive circuits constituting the row-direction drive circuit group include two drivers and drive value setting circuits for odd-numbered column lasers and even-numbered column lasers, respectively. However, the number of drivers and drive value setting circuits is not limited to two.
In consideration of the circuit size and the driving speed, 3
It may be configured to be alternately driven by one or more drivers.

In each of the above embodiments, only the method in which the row drive circuit drives the laser array with current has been described. However, a method in which voltage drive is performed instead of current drive may be adopted. Further, in each of the above embodiments, only the example in which the light emitting element array drive circuit of the present invention is applied to a laser array has been described. However, the light emitting element array is not limited to the laser array only, but may be a light emitting diode array or the like. The present invention can be applied to all light emitting element arrays used for the same purpose as the laser array.

In each of the above embodiments, the column drive circuit 4 (n) corresponds to the first drive circuit according to the present invention,
The row drive circuit 5 (m) corresponds to the second drive circuit according to the present invention. In each of the above embodiments, each of the second drive circuits, that is, the row drive circuit 5 (m) is provided with a plurality of drivers acting alternately and a drive value setting circuit. And a drive value setting circuit may be provided in each of the first drive circuits constituting the first drive circuit group.

[0034]

As described above, according to the light emitting element array drive circuit of the present invention, a plurality of drive circuits forming at least one of a row-direction drive circuit group and a column-direction drive circuit group are provided. The drive circuit includes a plurality of drivers that act alternately and supply a drive current or a drive voltage to the light emitting element according to the input drive value, and a drive value setting circuit that supplies a drive value to the drivers. Accordingly, the drive value setting time is extended, so that it is possible to realize a light emitting element array drive circuit capable of increasing the resolution and speed of the image recording apparatus.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a first embodiment in which a light emitting element array drive circuit of the present invention is applied to a laser array.

FIG. 2 is an explanatory diagram of an operation time of the first embodiment of the light emitting element array drive circuit of the present invention.

FIG. 3 is a circuit diagram showing a light emitting element array drive circuit according to a second embodiment of the present invention.

FIG. 4 is a circuit diagram illustrating a light emitting element array drive circuit according to a third embodiment of the present invention.

FIG. 5 is a graph showing a relationship between a driving current of a laser and a light amount.

FIG. 6 is a circuit diagram illustrating a light emitting element array drive circuit according to a fourth embodiment of the present invention.

FIG. 7 is a circuit diagram of a conventional laser array driving circuit.

FIG. 8 is an explanatory diagram of an operation time of a laser array driving circuit.

[Explanation of symbols]

 1 (m, n) Laser 2 (n) Column common line 3 (m) Row common line 4 First drive circuit group 4 (n) Column drive circuit 5 Second drive circuit group 5 (m) Row drive circuit 6 , 7 control circuit 8 (m) memory 9 (m) DA converter 10 (m) drive value setting circuit 11 (m) first latch 12 (m) second latch 51 (m) first driver 52 ( m) Second driver 53 (m) First auxiliary driver 54 (m) Second auxiliary driver 81 (m) First memory 82 (m) Second memory 91 (m) First DA converter 92 (m) second DA converter

Continued on the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI Technical display location H04N 1/23 103

Claims (4)

[Claims] 1. A light emitting element array driving circuit for driving a light emitting element array composed of a plurality of light emitting elements two-dimensionally arranged in a row direction and a column direction, wherein a plurality of light emitting elements constituting the light emitting element array are arranged. A first driving circuit group including a plurality of first driving circuits for driving a plurality of light emitting elements arranged in the corresponding column and corresponding to each of the columns, and a plurality of light emitting elements forming the light emitting element array A second driving circuit group including a plurality of second driving circuits provided corresponding to each row in which the elements are arranged and driving a plurality of light emitting elements arranged in the corresponding row; and a plurality of light emitting element arrays forming the light emitting element array The first driving circuit and the second driving circuit corresponding to the light emitting element simultaneously act on the light emitting element according to the input data corresponding to the light emitting element. To The light-emitting element is turned on, or the operation of at least one of the first drive circuit and the second drive circuit corresponding to the light-emitting element on the light-emitting element is prohibited. A control circuit for sequentially performing an operation of controlling whether the light emitting element is maintained in the light-off state for a plurality of light emitting elements constituting the light emitting element array, the first driving circuit group and the second driving A plurality of driver circuits constituting at least one of the drive circuit groups of the circuit group, the plurality of drivers alternately acting to supply a drive current or a drive voltage corresponding to an input drive value to the light emitting element; And a drive value setting circuit for supplying the drive value to the plurality of drivers. 2. The memory, wherein the drive value setting circuit is provided commonly for the plurality of drivers and stores the drive value, and the memory is provided for each of the plurality of drivers. A latch for temporarily storing the drive value read from the memory, and a DA converter for converting a digital signal representing the drive value stored in the latch into an analog signal and supplying the analog signal to a corresponding driver. 2. The light emitting element array driving circuit according to claim 1, wherein: 3. A plurality of driving circuits constituting one of the driving circuit groups, wherein, in addition to the plurality of drivers, an action on the light emitting element or inhibition of the action is performed simultaneously with the plurality of drivers in accordance with input data. 2. The light emitting element array drive according to claim 1, further comprising a driver that supplies a predetermined driving current or a driving voltage to the light emitting element regardless of a driving value supplied from the driving value setting circuit to be controlled. circuit. 4. A driving value supplied from the driving value setting circuit, wherein a plurality of driving circuits constituting the one driving circuit group act on a light emitting element independently of input data in addition to the plurality of drivers. 2. The light emitting element array driving circuit according to claim 1, further comprising a driver for supplying a predetermined driving current or a driving voltage to the light emitting element regardless of the driving current.