JPH01255371A - System for driving light emitting diode - Google Patents

Abstract

PURPOSE:To shorten a time necessary for lighting up a light emitting element by supplying an operating current to each light emitting element by means of a constant current source. CONSTITUTION:A constant current source 121 supplies a constant current to each light emitting element 111, a switching means 131 switches the supply route of the current, and each light emitting element 111 is lit up at a selected point. In such a way, the constant current source 121 executes a control to decrease an internal resistance and to cause the current to rapidly flow to the light emitting element 111 at the time of the switching by the switching means 131. Thus, the time necessary for the lighting can be shortened, and the original reading speed of an active optical sensor can be also made high- speed.

Description

[Detailed Description of the Invention] [Summary] For example, regarding a light emitting diode drive method in which light emitting diodes are sequentially turned on in order to supply light to a light receiving element, the present invention aims to shorten the time required for lighting. It is equipped with a plurality of light emitting elements made of light emitting diodes, a constant current source that supplies a constant current, and a switching means that selectively switches the current supply path from the constant current source to each light emitting element. The current supply path is selected by the switching means to light up the light emitting element.

[Industrial application field]

The present invention relates to a light emitting diode drive method G, for example, a light emitting diode drive method in which light emitting diodes are sequentially turned on to supply light to a light receiving element.

[Conventional technology]

Generally, in image reading devices, facsimile machines, etc. connected to word processors, a light emitting element emits light onto a document, and a light receiving element detects the reflected light or 15η excess light to read the image drawn on the document. .

Figure 4 shows a light emitting diode (hereinafter referred to as 71 t) as a light emitting element.
, ED) is shown. For example, if high resolution is required, such as in a facsimile machine or a copying machine, a plurality of LEDs 411 arranged in a line, . 411. , ・・
・Irradiates light onto the original 4I3 from a light emitting body consisting of
The reflected light from 13 is collected by a lens 415 and sent to a light receiving element 417 such as a phototransistor or a charge-coupled device (CCD).
It is detected by a photoreceptor consisting of 1.417t, .

In addition, in the case of a document that does not require high resolution, as shown in (b), the document 413 is irradiated with light from a light emitter, and the document 413 is
The reflected light is directly detected by the photoreceptor.

By the way, when the lens 415 is not used (case (b)), the light emitters are LED411+, 411□,...
・Constitutes a line light source, so the reflected light becomes scattered light,
The detected image information becomes blurred. For this reason, it has become necessary to scan the detection of irradiated light and reflected light.

FIG. 4(c) shows a circuit configuration for scanning the irradiation light. In the figure, the anode side of each LED 411 is connected to each resistor 421 (resistor 421+, 421
g, . . . ) to a constant voltage source 431. Further, the cathode side of each LED 411 is grounded via an LED selection circuit 441.

By sequentially switching the connection state using the LED selection selection 441, each LED 411 is sequentially turned on.

[Problem to be solved by the invention]

By the way, in the conventional method described above, the constant voltage source 43
1 supplies operating voltage to each LED 411, there is a problem that the current flowing through each LED 411 changes gradually, and it takes time to turn on the LED.

In particular, since the reading speed of a document depends on the scanning speed of the irradiation light, a method is desired in which the rise time of lighting each LED 411 is shortened as much as possible to shorten the scanning time.

The present invention was created in view of these points, and an object of the present invention is to provide a light emitting diode drive method that reduces the time required for lighting.

[Means to solve the problem]

FIG. 1 is a principle block diagram of a light emitting diode drive system according to the present invention.

In the figure, the plurality of light emitting elements 111 are made of light emitting diodes.

Constant current source 121 supplies constant current.

The switching means 131 switches the constant current source 121 to each light emitting element 1.
selectively switches the current supply path to 11.

Therefore, as a whole, the current supply path from the constant current source 121 is switched by the switching means 131, and each light emitting element 111 is selectively turned on.

[For production]

The constant current source 121 supplies a constant current to each light emitting element 111, and the switching means 131 switches the current supply path to selectively light up each light emitting element 111.

In the present invention, when switching by the switching means 131, the constant current source 121 reduces the internal resistance to reduce the internal resistance of the light emitting element 11.
1, the time required for lighting can be shortened.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

FIG. 2 shows the configuration of an embodiment to which the light emitting diode drive method of the present invention is applied. Further, FIG. 3 shows the overall configuration of an active optical sensor to which the light emitting diode drive method of the present invention is applied.

Here, the correspondence between the embodiment of the present invention and FIG. 1 will be shown.

The light emitting element 111 corresponds to the LED 211.

Constant current source 121 corresponds to constant current source 221.

The switching means 131 corresponds to the LED selection selection 231.

Examples of the present invention will be described below assuming that the correspondence relationship as described above exists.

■, 乍 1 J AND 1 In FIG. 2, the LED drive circuit to which the light emitting diode drive method of the present invention is applied is composed of a plurality of LEDs 21
1+, 211□, 2113. ...and each LED2
11, and an LED selection selection 231 for selecting a predetermined LED 211.

For example, the constant current source 221 is an operational amplifier 24.

Transistor 243 and three resistors 2m245, 247
．． It consists of 249.

A + side input terminal (in-phase side) of the operational amplifier 241 is connected to a resistor 247 and a resistor 249.

The other end of resistor 247 is connected to the operating voltage (+Vcc) line, and the other end of resistor 249 is grounded.

Moreover, one side input terminal (opposite phase side) of the operational amplifier 241 is
It is connected to the emic side of the resistor 245 and the transistor 243. The other end of the resistor 245 is connected to the operating voltage (+V
cc) line, and the base side of the transistor 243 is connected to the output terminal of the operational amplifier 241.

Furthermore, the collector side of the transistor 243 is connected to each LED 21.
1, and the cathode side of each LED 211 is grounded via an LED selection circuit 231.

The operational amplifier 241 of the constant current source 221 is connected to the transistor 2
By monitoring the emitter side potential of 43, the current value supplied to each LED 211 via the transistor 243 is adjusted.

For example, the selection by the LED selection circuit 231
1. Consider the case where the LED 211□ is switched from the LED 211□. L
When ED211□ is selected (the cathode side is grounded), the constant current source 2
21 controls the internal resistance to be small and rapidly supplies current to the LED 211z. When the current value supplied to the LED 211□ is small, the emitter side potential of the transistor 243 is in a high state, and the operational amplifier 241 controls the transistor 243 according to this potential, so that the current value supplied from the constant current source 221 to the LED 211□ is high. The current value is kept constant.

By the above operation, an operating current is supplied to the LED 211□, and the LED 211□ lights up.

Further, FIG. 3 shows an example of an active optical sensor using the LED drive circuit shown in FIG. 2.

In the figure, light emitted from each LED 211 is reflected by a document 351. A light receiving element 311 that detects reflected light from the original 351. ．． 311g, 311:+,
. . corresponds to each LED 211, and the output of each light receiving element 311 is supplied to an amplifier circuit 331 via a multiplexer 321. The amplifier circuit 331 amplifies and outputs the output of the light receiving element 311 supplied from the multiplexer 321. For example, each light receiving element 311 is
- When configured with a transistor, a photocurrent is obtained as an output of the light receiving element 311, and this photocurrent is amplified by the amplifier circuit 331.

The scan control unit 341 also controls the selection operations of the LED selection circuit 231 and the multiplexer 321, and
Di! The stream circuit 231 and the multiplexer 321 are synchronized. For example, when the LED 2111 is emitting light, the output of the light receiving element 311 is enabled, and only the output of the light receiving element 311+ is supplied to the amplifier circuit 331.

(2) Summary of - In this way, the constant current source 221 supplies operating current to each LED 211. When the L-length selection circuit 231 is switched, the operating current is rapidly supplied to the corresponding LED 211 until it reaches a predetermined current value, so the time required for lighting the LED 211 can be shortened.

Further, by shortening the lighting time of each LED 211, it is also possible to increase the document reading speed of an active optical sensor as an application example.

■, B-no-hi ・Although the correspondence between the present invention and the embodiments has been explained in "■, Correspondence between the embodiments and FIG. 1", the present invention is not limited to this. Those skilled in the art will easily guess that there are various modifications to the present invention.

〔Effect of the invention〕

As described above, according to the present invention, by supplying operating current to each light emitting element using a constant current source, the time required for lighting the light emitting elements can be shortened, so it is extremely useful in practice. be.

[Brief explanation of the drawing]

Fig. 1 is a principle block diagram of the light emitting diode drive method of the present invention, Fig. 2 is a block diagram of an embodiment to which the light emitting diode drive method of the present invention is applied, and Fig. 3 is an active optical sensor of the embodiment. FIG. 4 is a block diagram of a conventional active optical sensor. In the figure, 111 is a light emitting element, 121 is a constant current source, 131 is a switching means, and 211 is an LED. 221 is a constant current source, 231 is an LED selection circuit, 241 is an operational amplifier, 243 is a transistor, 245, 247, 249 are resistors, 311 is a light receiving element, 321 is a multiplexer, 331 is an amplifier circuit, 341 is a scan control section, 351 is a manuscript. Figure 1 Configuration diagram of tip #II Figure 2 (A) (B) Conventional A7 tip No. 4 (C) Configuration diagram of Kozen f

Claims (1)

[Claims] (1) Multiple light emitting elements (111) consisting of light emitting diodes
a constant current source (121) that supplies a constant current, and a switching means (131) that selectively switches a current supply path from the constant current source (121) to each of the light emitting elements (111).
A drive for a light emitting diode, comprising the following: a current supply path from the constant current source (121) is selected by the switching means (131) to light up the light emitting element (111). method.