JP2846136B2 - Driving method of light emitting element array - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for driving a light emitting element array formed by integrating a large number of light emitting elements on the same substrate, and more particularly to extending the life of the light emitting element array.

[0002]

2. Description of the Related Art A light emitting element array in which a large number of light emitting elements are integrated on the same substrate is used as a writing light source for an optical printer or the like in combination with a driving IC. The present inventors have paid attention to a light-emitting thyristor having a PNPN structure as a component of a light-emitting element array, and have already filed a patent application (Japanese Patent Laid-Open No. 1-238962) that can realize self-scanning of a light-emitting point.
JP-A-2-14584, JP-A-2-92650
And Japanese Patent Application Laid-Open No. Hei 2-92651) that the light source for an optical printer can be easily mounted, the pitch of the light emitting elements can be reduced, and a compact light emitting device can be manufactured.

As an example of these inventions made by the present inventors, FIG. 4 shows a light-emitting element array capable of self-scanning by two-phase clock driving using potential coupling by a diode disclosed in JP-A-2-14584. Show. Both φ ₁ and φ ₂ are transfer clock pulses in which the ratio (duty ratio) between the high level time and the low level time is approximately 1: 1, and V _GK is a power supply (normally 5 V). T (1)-T
(5) is a light emitting thyristor used as a light emitting element, D
_{1 to} D ₅ are potential coupling diodes, and G _{1 to} G ₅ are gate electrodes of the light emitting thyristors T (1) to T (5). R _L
Is the load resistance of the gate electrode, which limits the current to the gate electrode.

The operation will be briefly described. First, when the voltage of the transfer clock pulse φ ₂ is at a high level, the light emitting thyristor T
It is assumed that (2) is in the ON state (light emitting state). At this time, the potential of the gate electrode G ₂ is lowered to almost zero V from 5V to V _GK. The effect of this potential drop is transmitted by the diode D ₂ to the gate electrode G _3, and sets the potential of about 1V. However, since the diode D ₁ is in a reverse bias state, no potential is connected to the gate electrode G _1, and the potential of the gate electrode G ₁ remains at 5V. Since on the potential of the light-emitting thyristor is approximated by the gate electrode potential + a diffusion potential (about 1V), the next high-level voltage of the transfer clock pulses phi ₁ necessary to turn on about 2V (the light-emitting thyristor T (3) If the voltage is set to not less than about 4 V (the voltage required to turn on the light-emitting thyristor T (5)), only the light-emitting thyristor T (3) is turned on, and the other light-emitting thyristors are turned off. Can be left as is. Therefore, the light emitting state is transferred by two transfer clock pulses.

FIG. 5 shows an example in which the light emitting element array of FIG. 4 is formed on the same semiconductor substrate. A GaAs PNPN structure is formed on an N-type GaAs substrate, and the structure shown in FIG. 5 is formed by a technique such as photoetching.

In order to write (expose) an image on a photosensitive drum of an optical printer, it is necessary to apply energy equal to or more than a certain minimum energy to the photosensitive drum. Energy given to the photosensitive drum is given by a product of a light emitting time of a light emitting element corresponding to a position where an image is to be written and a light emitting intensity of this element. Therefore, in order to use the light emitting element array of FIG. 4 as a light source for an optical printer, not only the transfer of the light emitting point, but also the modulation of the light emission intensity is required. ing.

FIG. 6 shows a simplified driving method of a light emitting element array for modulating light emission intensity of a light emitting element according to Japanese Patent Application Laid-Open No. 1-238962. The circuit of FIG. 6 has the same configuration as that of the first embodiment except that the clock lines providing the emission intensity modulation clock pulses (current pulses) φ _I1 and φ _I2 are connected to the clock lines providing the transfer clock pulses φ ₁ and φ ₂ , respectively. It is the same as FIG. Both the transfer clock pulses φ ₁ and φ ₂ have a ratio (duty ratio) between the high-level time and the low-level time of approximately 1: 1.
And substantially mutually inverted pulses. The emission intensity modulation clock pulses φ _I1 and φ _I2 are at a high level only when the light emitting element corresponding to the position where the image is to be written is in a light emitting state (the current value is the light emitting time and the light emitting intensity at this time). The product is set to be equal to or higher than the minimum energy for writing an image on the photosensitive drum). as a result,
A current is applied to the corresponding clock line, and the light emission intensity of the light emitting element corresponding to the position where an image is to be written increases,
The minimum energy can be applied to the photosensitive drum.

[0008]

However, when the light emission intensity of the light emitting element corresponding to the position where an image is to be written is increased by the above method, the amount of current flowing through the light emitting element also increases. It is known that the life of a light-emitting element is shortened at an accelerating rate with an increase in the amount of current flowing through the element. In particular, when a large current flows, the life of the light-emitting element is significantly reduced. Therefore, when the light emission intensity is modulated by the method disclosed in Japanese Patent Application Laid-Open No. 1-238962, the life of the light emitting element is shortened.

An object of the present invention is to provide a driving method of a light emitting element array capable of modulating the light emission intensity of the light emitting element without shortening the life of the light emitting element.

[0010]

In order to solve the above-mentioned object, a driving method of a light-emitting element array according to the present invention has a light-emitting time of a light-emitting element for which light-emitting intensity is to be increased, compared with a light-emitting time of another light-emitting element. The configuration was made longer. That is, a light-emitting element having a gate electrode for controlling a threshold voltage or a threshold current and an anode electrode to which an external voltage or an external current is applied according to the present invention is one-dimensional, two-dimensional or three-dimensional. A plurality of light-emitting elements, and a gate electrode of each of the light-emitting elements is connected to a gate electrode of at least one of the light-emitting elements located near the light-emitting element via electrical means to form a network wiring; A plurality of clock lines, each of which individually applies a first group of clock pulses, which are signals for transferring the light emitting state of the light emitting element to another light emitting element, are connected one by one to the anode electrode of each light emitting element, A current source for supplying a second group of clock pulses, which is a signal for increasing the light emission intensity of the light emitting element, is connected to each of the clock lines. Dynamic method,

The first group of clock pulses shifts the high level to another first group of clock pulses while overlapping the high level times with each other for a short period of time, and causes the light emitting element to increase the light emission intensity to emit light. The high-level time of the clock pulse of the first group is substantially the same length when any of the light-emitting elements whose emission intensity is to be increased is emitted, and the light-emitting elements that do not increase the emission intensity are set to the emission state. The high-level time of the clock pulse of the first group is substantially the same for all the light-emitting elements that do not increase the light-emission intensity.
The high-level time of the first group of clock pulses when the light-emitting element that increases the light-emitting intensity is in the light-emitting state is the high-level time of the first group clock pulse when the light-emitting element that does not increase the light-emitting intensity is in the light-emitting state. Sufficiently longer than the time, the second group of clock pulses is set to a high level only when the corresponding first group of clock pulses is at a high level and when the light emission intensity of the light emitting element that is emitting light at that time is increased. It is characterized by becoming.

That is, the conventional transfer clock pulse is:
Both the light-emitting element that increases the light-emitting intensity and the light-emitting element that does not increase the light-emitting intensity emit light for the same time (all high-level times and low-level times have the same length), but in the present invention, The transfer clock pulse is controlled so that the light emitting time of the light emitting element that increases the light emitting intensity is longer than the light emitting time of the light emitting element that does not increase the light emitting intensity. At the same time, the emission intensity modulation clock pulse goes high only when the corresponding transfer clock pulse is at the high level and the emission intensity of the light emitting element emitting light at that time is increased.

In the present invention, the minimum number of clock lines to which the transfer clock pulse is individually applied is sufficient for the light emitting state transfer operation.
The number may be more than the minimum number necessary for the light emitting state transfer operation. Further, the product of the time for increasing the light emission intensity and the light emission intensity at that time is set to be equal to or more than the minimum energy for writing an image on the photosensitive drum. Further, the present invention can be applied to a light emitting element array formed by arranging switch elements and light emitting elements together. Further, the number of current sources for supplying the second clock pulse is the same as the number of clock lines, and each may be connected one-to-one, or only one current source is provided, which is used for all clock lines. May be connected in common.

[0014]

According to the present invention, since the light emission time of the light emitting element for increasing the light emission intensity is considerably longer than that of the conventional light emitting element, when the above-described minimum energy is applied to the photosensitive drum, the light emission element when the light emission intensity is increased is provided. Can be made much weaker than before. That is, since the current at the time when the emission intensity modulation clock pulse (current pulse) is at the high level can be reduced, the amount of current flowing to the light emitting element for increasing the emission intensity can be reduced, thereby extending the life of the light emitting element. Life can be extended.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to FIGS.
This will be described with reference to FIG.

FIG. 1 is a view showing a first embodiment of the present invention. FIG. 1A shows a case where the above-described light emitting element array is used as a light source for an optical printer. Since the resolution of the optical printer is 400 DPI (dots per inch), about 3300 light-emitting elements are arranged one-dimensionally on one short side line (about 21 cm) of the A4 size.
In this case, 26 light-emitting element arrays in which 128 light-emitting elements are arranged one-dimensionally are connected in series to form a one-dimensional light-emitting element array including 3328 light-emitting elements. The circuit configuration is the same.

FIG. 3B is a diagram showing a method for driving the light emitting element array according to the present invention for causing the circuit in FIG.

The transfer clock pulses φ ₁ and φ ₂ and the emission intensity modulation clock pulses φ _I1 and φ I shown in FIG.
FIG. 2 shows a block diagram for obtaining _I2 . First, image information is stored in a one-line memory (1). This image information is sent from the one-line memory to the light-emission intensity modulation element number counter (2), and the number of light-emission elements for increasing the light-emission intensity per line is calculated.

This calculation result, the time allocated to one line, and the high-level time of the transfer clock pulse when the light emitting element that does not increase the light emission intensity is set to the light emitting state (in this embodiment, the light emitting element array is operated) 0.1 μsec [S. Ohns, et al., Exte
nded Abstract of the 22nd Conference on Solid Stat
e Device and Materials, Sendai 1990, pp801-804]) and the high-level time of the transfer clock pulse when the light emitting element that increases the light emission intensity is turned on (one light emitting element (Writing time to the photosensitive drum) is calculated by the light emission intensity modulation element number counter.

In this embodiment, the time allocated to one line is 1.28 msec, and the number of light emitting elements for increasing the light emission intensity for one line is 166 (corresponding to a normal blackening rate (5%)). I do. Then, the high-level time of the transfer clock pulses φ ₁ and φ ₂ when the light emitting element for increasing the light emission intensity is set to the light emitting state is (1.28 ms-
(0.1 μs × 3300) ÷ 166 = 5.7 μsec.
This is about one time shorter than the high level time of the conventional transfer clock pulse (1.28 msμ3300 = 0.39 μsec).
Five times as long.

The above calculation result (4) by the light emission intensity modulation element number counter and the image information from the one-line memory (3)
Are sent to the transfer clock pulse generator. The transfer clock pulse generator sets the high-level time when the light-emitting element that increases the light-emission intensity is in the light-emitting state to 5.7 μs and the high-level time when the light-emitting element that does not increase the light-emission intensity is in the light-emission state. The transfer clock pulses φ ₁ and φ ₂ having 0.1 μsec are generated (FIG. 1 shows the light emitting element T
(2), transfer clock pulses φ ₁ and φ ₂ for increasing the light emission intensity of T (7) are shown). The transfer clock pulses φ ₁ and φ ₂ are sent to the light emission intensity variation correction memory (5), the light emission intensity modulation clock pulse generator (6), and the light emitting element array (7).

Emission intensity variation correction memories are provided one by one.
The variation of the light emission intensity of the two light emitting elements is stored, and is used for fine adjustment of the high-level current value of the light emission intensity modulation clock pulse.

By incorporating the signal (8) from the emission intensity modulation element number counter, the signal (9) from the emission intensity variation correction memory and the signal (6) from the transfer clock pulse generator, The clock pulse generator generates a clock pulse φ _I1 for emission intensity modulation,
Generates _φI2 . In FIG. 1, the light emitting elements T (2) and T (7)
The clock pulse for emission intensity modulation in which φ _I2 and φ _I1 are at a high level only when is emitted is shown. The emission intensity modulating clock pulses φ _I1 and φ _I2 are sent to the light emitting element array (10). By the above means, the transfer clock pulse and the emission intensity modulation clock pulse shown in FIG. 1B are obtained.

Next, the pulse shown in FIG.
The operation of (A) will be described. First, the low level of the start pulse phi _S (approximately 0V) to simultaneously transfer clock pulses phi ₁ to the high level (about 2 to about 4V), causes the light emitting elements T (1). Shortly thereafter, the start pulse φ
_S is returned to high level.

Next, in order to transfer the light emitting state of the light emitting element T (1) to the light emitting element T (2), the transfer clock pulse φ _{2 is set} to the high level while the light emitting element T (1) remains emitting light. (About 2 to about 4 V). Then, the light emitting element T (2)
Emits light. Then since immediately transfer clock pulses phi ₁ the low level light emitting element T (1) is turned off (transfer clock pulses phi ₁ at this time was a high level between 0.1 .mu.s). After the light-emitting element T (2) emits light and at substantially the same time, the light-emitting intensity modulation clock pulse φ _{I2 is set} to the high level. Then, the light emitting element T
The current flowing to (2) increases, and the light emitting element T (2) increases the light emission intensity.

Next, in order to transfer the light emission state of the light-emitting element T (2) to the light emitting element T (3), the light-emitting element T (2) the transfer clock pulses phi ₁ to the high level in a state where the light-emitting (About 2 to about 4 V). Then, the light emitting element T (3)
Emits light. Soon after transfer clock pulses phi ₂ is the light emitting element becomes a low level T (2) is turned OFF (transfer clock pulses phi ₂ at this time was high between 5.7μs). Light emitting elements T (3), T (4), T
(5) and T (6) emit light for 0.1 μs each, and transfer the light emitting state to the next light emitting element. Light emitting element T
(7) emits light for 5.7 μs, during which the emission intensity modulation clock pulse φ _I1 is set to the high level. Hereinafter, the light emitting state is transferred to the light emitting element T (3328). During this time, the light emitting intensities of the 166 light emitting elements including the light emitting elements T (2) and T (7) are changed to the light emitting intensity modulating clock pulse φ _I1 ,
Increased by _φI2 .

In the above process, the product of the light emission intensity of the light emitting element having the increased light emission intensity and the time during which the light emission intensity has been increased is the minimum value for exposing the photosensitive drum of the optical printer to light. The emission intensity is adjusted. These 166 light-emitting elements write an image, and the current flowing therethrough can be suppressed to about 1/15 of the conventional value. Therefore, the life of these light emitting elements is extended, and the life of the entire light emitting element array is extended.

In the above embodiment, the case where the light emission intensity of 166 light emitting elements is increased has been described. However, if the number of elements for increasing the light emission intensity is, for example, twice (332), the high-level time of the corresponding transfer clock pulse is halved, so the light emission intensity must be doubled. That is, the number of light emitting elements that increase the light emission intensity per line must be controlled so that the light emission intensity and the light emission time are always equal to or more than the above-described minimum energy.

In the above embodiment, the number of light emitting elements in one line in the light emitting state has been described as one.
The present invention is not necessarily limited to this. For example, 128
In a one-dimensional light-emitting element array including 3328 light-emitting elements in which 26 light-emitting element arrays in which two light-emitting elements are arranged one-dimensionally are connected in series, one light-emitting element array including 128 light-emitting elements is provided. The light emitting elements in the light emitting state may be provided each, and the 26 light emitting states may be transferred. In this case, 1.28 milliseconds are allocated to 128 elements. Therefore, if the blackening rate is calculated as 5% in the same manner as in the above-described embodiment, the image writing is performed with a current amount 1/18 of the conventional method. It can be performed.

FIG. 3 is a view showing a second embodiment of the present invention, in which a light emitting element array is used as a light source for an optical printer in the same manner as in FIG. The circuit of the upper half of the part (A) is the light emitting elements T (1) to T (1) in FIG.
(4) is replaced with switching elements S (1) to S (3328) to further increase the number. The gate electrode of each switch element is a pair with the switch element.
It is connected to the gate electrodes of the light emitting elements. As a result, each light emitting element is in a light emitting state when the corresponding switch element is in an on state. Further, the anode electrode of the light emitting element, a current source for supplying a common emission intensity modulating clock pulses phi _I is connected.

The transfer clock pulses φ ₁ and φ ₂ are shown in FIG.
This is a pulse generated by exactly the same procedure as in (B), and its waveform is also the same as in FIG. 1 (B). in this case,
Only the light emitting elements T (2) and T (7) can increase the light emission intensity. Luminous intensity-modulated clock pulse phi _I becomes a high level only when either of the light-emitting element T (2) and T (7) is emitting light.

The operation is exactly the same as that of the first embodiment shown in FIG. Difference from the first embodiment, the method comprising emitting intensity-modulated clock pulse there is only one kind, the light emitting intensity-modulated clock pulse phi _I in this case, light emission intensity modulation in the first embodiment It is a waveform obtained by superposing the waveforms of the clock pulses φ _I1 and φ _I2 for use. Also in this embodiment, the light emission intensity is controlled by the number of light emitting elements that increase the light emission intensity. Further, the number of light-emitting elements in a light-emitting state can be increased.

In the first and second embodiments described above, the example in which the number of clock lines is two has been described. However, the present invention is not limited to this, and the number of clock lines is three. It is also possible to carry out with more than this. Also,
In the above description, the clock pulse is of a two-phase drive type of a high level and a low level, but the present invention can be applied to a clock pulse of a three-phase drive type. Further, the coupling portion of each light emitting element is not limited to a diode, and may be an electrical coupling means such as a transistor or a resistor. Further, the light-emitting element array to which the present invention can be applied is not limited to the light-emitting element array in which the light-emitting elements are arranged one-dimensionally as described above, and the light-emitting element array in which the light-emitting elements are arranged two-dimensionally or three-dimensionally. It may be.

[0034]

According to the present invention, the life of each light-emitting element constituting the light-emitting element array is extended, so that the long-term reliability of equipment using the light-emitting element array can be increased.

[Brief description of the drawings]

FIG. 1 is a diagram showing a first embodiment of a method for driving a light emitting element array according to the present invention.

FIG. 2 is a block diagram for obtaining a clock pulse shown in FIG.

FIG. 3 is a diagram showing a second embodiment of the method for driving the light emitting element array according to the present invention.

FIG. 4 is a diagram showing a driving method of a light emitting element array proposed in Japanese Patent Application Laid-Open No. 2-158484.

FIG. 5 is a schematic diagram of a partial cross-sectional structure of the light-emitting element array shown in FIG.

FIG. 6 is a diagram showing a simplified driving method of a light emitting element array proposed in Japanese Patent Application Laid-Open No. 1-238962.

[Explanation of symbols]

T (1) Light emitting element T (2) Light emitting element T (3) Light emitting element T (4) Light emitting element T (5) Light emitting element D ₁ coupling diode D ₂ coupling diode D ₃ coupling diode D ₄ coupling diode D ₅ coupled diode phi ₁ transfer clock pulses phi ₂ transfer clock pulses phi _I1 luminous intensity-modulated clock pulse phi _I2 luminous intensity-modulated clock pulse phi _I emission intensity modulating clock pulse phi _S start pulse

Continuation of the front page (56) References JP-A-49-129492 (JP, A) JP-A-2-92650 (JP, A) JP-A-2-92651 (JP, A) JP-A-2-212170 (JP) , A) JP-A-2-206767 (JP, A) JP-A-48-96291 (JP, A) JP-A-1-238962 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB Name) B41J 2/44 B41J 2/30 B41J 2/45 B41J 2/455

Claims (6)

(57) [Claims] A light-emitting element having a gate electrode for controlling a threshold voltage or a threshold current and an anode electrode to which an external voltage or an external current is applied is formed in a one-dimensional, two-dimensional or three-dimensional manner. A large number of the light emitting elements are arranged, and the gate electrode of each light emitting element is connected to the gate electrode of at least one of the light emitting elements located in the vicinity of the light emitting element via electrical means to form a network wiring. A plurality of clock lines for individually applying a first group of clock pulses, which are signals for transferring a light emitting state to another light emitting element, are connected one by one to the anode electrode of each light emitting element, and A current source for supplying a second group of clock pulses, which is a signal for increasing the light emission intensity of the element, is used in a method of driving a light emitting element array connected to each of the clock lines. The first group of clock pulses shifts the high level to another first group of clock pulses while overlapping the high level times with each other for a short time, and sets the light emitting element to increase the light emission intensity to the light emitting state. The high-level time of the clock pulse of the first group is substantially the same length when any of the light-emitting elements whose emission intensity is to be increased emits light, and the light-emitting elements that do not increase the emission intensity are set in the light-emitting state. The high-level time of the first group of clock pulses is substantially the same length when any of the light-emitting elements that do not increase the light-emitting intensity is emitted, and when the light-emitting element that should increase the light-emitting intensity is in a light emitting state. The high-level time of the first group of clock pulses corresponds to the first group of clocks when the light emitting element that does not increase the light emission intensity is set in the light emitting state. The second group of clock pulses, which is sufficiently longer than the high-level time of the pulse, is used when the corresponding first group of clock pulses is at a high level and the emission intensity of the light-emitting element that is emitting light at that time is increased. A method for driving a light emitting element array, wherein only the high level is set. 2. A one-dimensional set comprising a switch element and a light emitting element each having a gate electrode for controlling a threshold voltage or a threshold current and an anode electrode to which an external voltage or an external current is applied. A plurality of gate electrodes of each of the switch elements, a gate electrode of at least one switch element located near the switch element, and a set of each of the switch elements. Forming a network wiring by connecting to the gate electrode of the light emitting element to be formed via electrical means,
A plurality of clock lines that individually apply a first group of clock pulses, which are signals for transferring the on state of the switch element and the light emitting state of the light emitting element to the other set of switch element and light emitting element, respectively. A current source that is connected one by one to the anode electrode of each of the switch elements and supplies a second group of clock pulses, which is a signal for increasing the emission intensity of the light-emitting element, to the anode electrode of each of the light-emitting elements In the driving method of the connected light emitting element array, the first group of clock pulses shifts a high level to another first group of clock pulses while overlapping a high level time with each other for a short time, thereby increasing the light emission intensity. First when the light emitting element to be caused to emit light
The high-level time of the clock pulse of the group is substantially the same length when all the light-emitting elements whose emission intensity is to be increased are made to emit light, and the first group when the light-emitting elements that do not increase the emission intensity are made to emit light. The high-level time of the clock pulse is substantially the same length when any of the light-emitting elements that do not increase the light-emission intensity is caused to emit light. The high-level time of the clock pulse is sufficiently longer than the high-level time of the first group of clock pulses when the light emitting element that does not increase the light emission intensity is set to the light emitting state, and the second group of clock pulses is corresponding to the light emission. A light-emitting element in which the element is in a light-emitting state and is at a high level only when the light-emitting intensity of the light-emitting element that emits light is increased. Driving method of the array. 3. A high-level time of a first group of clock pulses when the light emitting element whose light emission intensity is to be increased is set to a light emitting state, is a maximum time determined by the number of the light emitting elements increasing light emission intensity, or 3. The method for driving a light-emitting element array according to claim 1, wherein the time is less than or substantially equal to the time. 4. The product of the light emission intensity of the light emitting element when the light emission intensity is increased and the time during which the light emission intensity is increased is a minimum value for exposing a photosensitive drum of an optical printer, or more. 4. The method of driving a light emitting element array according to claim 1, wherein the light emission intensity is determined so as to be a value sufficiently close to the value. 5. The method according to claim 1, wherein the number of clock pulses constituting the second group of clock pulses is one, and a current source for supplying the clock pulses is commonly connected to all clock lines. Or the driving method of the light emitting element array according to 4. 6. The method according to claim 2, wherein the number of clock pulses constituting the second group of clock pulses is one, and a current source for supplying the clock pulses is commonly connected to all the light emitting elements. Or the driving method of the light emitting element array according to 4.