DD205307A1 - LIGHT MASTER INDICATORS WITH VARIABLE SWITCH VOLTAGES AND BRIGHTNESS CONTROL - Google Patents

Abstract

The invention relates to a solution display with variable switching voltages and harshness control which provide more display and signaling capabilities in equipment. The object of the invention is to extend the applicable operating voltage of light emitting displays without additional external circuitry by an integrated circuit arrangement from 2V to 50V , According to the invention, this object is achieved by integrating one or more light-emitting chips, each with one and / or an integrated constant-current generator and / or voltage-dependent multivibrator and / or other circuit arrangements guaranteeing the current constancy and / or pulsed control, into a structural unit in a common housing The displays according to the invention can be used without external wiring in communications technology, in the automotive industry in mechanical engineering, in the appliance industry, in mining and in measuring technology.

Description

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Title of the invention

Light emitter displays with variable switching voltages and brightness control

Field of application of the invention

Light-emitting displays based on semiconductor materials, in particular GaP. GaAsP, GaAlAs can only be operated at specific currents and voltages without integrated drive circuits.

Variable-voltage light-emitting displays in devices and systems offer more display and signaling capabilities. By extending the voltage range up to 50 V with the same working current, the field of application of the light emitter displays increases considerably. Thus, without additional circuitry and low additional power requirements, the light emitter displays can be used in the automotive industry, in mechanical engineering, in communications engineering, in equipment construction, in mining, in the construction industry and in measurement technology.

Characteristic of the known technical solutions

Known are red-emitting light emitter displays with series resistor. The integrated ohmic resistor eliminates the need for external wiring up to a maximum operating voltage of 7.5 V. The breakdown voltage is at least 3 V. The LED 5082 - 4860 / 446g (hp brochure: RTG E Springorum GmbH 2000 Hamburg 70) with series resistor has the disadvantage that at an operating voltage of 7.5 V more than 5 V drops across the integrated resistor, resulting in an increased power consumption and a

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Heating the diodes leads. As a result, the reliability of the device is lowered.

In addition, light-emitting devices with series resistor and protective diode in the miniature housing are known (HLMP - 6600/6620 hp brochure RTG). The additionally series-connected protection diode extends the maximum reverse voltage range from the typical value of 7.5 V to a maximum of 15 V for the light-emitting diodes. The existing ohmic resistance is to guarantee a reliable flow of current up to a maximum operating voltage of 6 V.

Also known are light emitter inductors with integrated voltage comparator (hp 5882-4732) The integrated circuit includes a voltage comparator which compares the externally applied voltage with an internally generated threshold voltage and switches the light emitting diode on when the threshold voltage is exceeded Series connection of external components such as Zener diodes, the switching voltage can be varied.

The disadvantage of this arrangement according to the principle of the comparator is that only one reference voltage can be specified internally. A variation of the threshold voltage is not possible. In addition to these arrangements, devices are known which perform flashing functions in conjunction with integrated circuit circuits. The switching voltage remains constant (brochure material, litronix: Flashing Light Emitting Diode, Red-Lit 4403, Omni Ras GmbH 8000 Munich 19).

Object of the invention

The object of the invention is to expand the applicable operating voltage of light-emitting displays without additional external circuitry. This means that the components should be connected without external wiring up to maximum operating voltages of z. B. 50 V to operate. The increase of the operating voltage of z. B. 50 V should be realized by an integrated circuit arrangement. The connection pins or the design of the light emitting device should be kept as possible. The power requirement

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should be low and the reliability of the components high. Explanation of the essence of the invention

The object of the invention is to expand the field of application of light-emitting displays without external Beschältung of 2 V to 50 V variable. According to the invention, the object is achieved in that an integrated circuit arrangement is realized in an integrated design and connected to the light-emitting components. The drive circuit is mounted on the same carrier strip as the light emitting device. In this case, on the integrated circuit bonding islands for Kon'taktierung provided with the light-emitting displays and / or the outer terminals.

Furthermore, the circuit chip is disposed below the light-emitting diode chip. The Lichtemitteranzeiyen be glued on the circuit chip, electrically connected by thermocompression or by conventional bonding method with the circuit. The circuit arrangement is designed as a constant current source. The constant current source is realized in the simplest case by two transistors, a high and a low resistance. The size of the low-ohmic resistor determines the constant current of the light emitter display. This is done in such a way that a parallel connection of resistors is provided in the lay-out and the desired current is provided by different contacting in the Leitbahnebene.

Furthermore, by applying a fixed current surge parallel connection branches are burned and thus set a constant current depending on the application.

Another way of line balancing the light emitter display is to integrate a voltage-dependent multivibrator to the constant current generator. When the voltage is increased, the duty cycle or the frequency of the multivibrator is increased and thus less power is converted via the load resistor.

23 APR 19 8 / * 00 4 771

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These integrated drivers are used both in single diodes and for diode arrays such as rows, numeric and alphanumeric arrays. When using multi-color chips, ie when a part of the chips emits red and green light, for example, the colors can be switched on step by step depending on the doping, the material used and the applied voltage, or mixed light can be switched in a voltage-dependent manner from red and green emitting diodes , The use of two and three-chip types for realizing Mehrfarblichtemi t terdioden it is advantageous before, to integrate a drive circuit under or next to each diode chip or row.

In addition to the functions of constant current hold, the reduction of the power consumption by increasing the Tastverhai trusses in response to the applied voltage, the drive circuit takes a brightness control. The brightness control is carried out according to the invention dynamically and statically.

In the case of the static brightness control, the level of the constant current is determined by blowing a printed conductor on the drive chip by applying a prescribed voltage from the outside once. In the dynamic brightness control, a photoreceiver is integrated, which controls the duty cycle of the voltage-dependent multivibrator depending on the incident light and thus determines the brightness of the light emitter display. According to the invention, the photoreceiver is integrated in or on the substrate material of the drive circuit and contacted and / or applied as a single chip. When installing such circuits in display units, which have the structural design of a light well, the brightness control is limited by the fact that light incident on the side of the component. To reduce or prevent the entry of light from the outside into the component or to prevent the emission of the emitted light of the diode chip to the outside, according to the invention, the diode chips placed on mesageätzte hills or used in example embossed wells, which cause a reflective effect.

The mesa hems and / or the reflective troughs are realized from printed circuit boards, for example cenausite, ceramic or film carriers.

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embodiment

The invention will be explained below with reference to exemplary embodiments _t

FIG. 1 shows the circuit diagram for the integrated constant current source. The constant current source is defined by two transistors 1 and 2, by a high-impedance 3 and a tu taer ohmic resistor 4, the constant current through the light-emitting diode 5. The operating voltage is applied to the contacts 6 and 7. The mounting of the constant current source is indicated in FIG. In addition to the diode chip 8 is mounted in the realized in integrated form constant current source 9 in the reflector 10. Through the bonding wires 11, the integrated circuit with the diode chip 8 and the terminal contacts 12 is connected.

In light shaft displays, the light of an approximately mounted in the center of the light shaft light source is guided by the well-reflective walls of the light shaft so that at the upper end of the light shaft, a substantially homogeneous luminance is achieved.

FIG. 3 shows the principle of such an arrangement. On an electrically insulating material 13 necessary for the power supply of the light source tracks 140 and 146 are applied. These tracks can also be encapsulated by an insulating material. The light source 17 is fixed, for example, by an electrically conductive substance 18 and the second electrical connection is obtained via a conductor wire 16. Due to the design of the well-reflecting light shaft walls 15 as homogeneous a light distribution at the upper Aus¬ tri'ttsöf fung of the light shaft is achieved. In Figure 3, the "seal" of the light source carrier is shown idealized, ie it can no light _r in any existing neighboring light shafts ("light crosstalk") enter or leave the display side. The largest part 20 of the emitted light leaves the light shaft at the upper outlet opening; only a small portion 19 is lost through the insulation gap 23 of the two interconnects 14a and 14b. The surfaces of these are also very reflective. In this way it would be possible to use about 80 % of the emitted light of the light source 17.

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Due to the manufacturing tolerances, it is not possible in practice to achieve the ideal case (FIG. 3). The figure shows the realistic case Between the light shaft walls 15 and the light source body remains a gap 22 through which up to 30 % of the light 21 emitted by the light source can be lost. The aim is to largely avoid these losses by the light exit 21 almost completely and the small part of the emitted light 19 partially prevented by changing the light source mounting location to the reflector body or by additional reflective barriers whose shape must be coordinated with the shape of the light shaft walls and · is used to increase the luminance at the upper opening of the light shaft. In the following basic exemplary embodiments, this idea should be clarified.

By increasing the mounting location of the light source relative to its surroundings (FIG. 5), the light source is further introduced into the light well body, thereby greatly reducing the direct leakage of the light through the gaps 22 and 23.

In this variant, it may be necessary for technological reasons, the conductor 14 b of the lead wire 16 also increase. FIG. 6 shows a variant in which the light exit through the gap 22 is prevented by a reflective barrier on the conductor tracks 14a and 14b. In order to obtain the best possible homogeneity of the luminance at the upper light shaft opening, the shape of the reflective barrier must be matched to the shape of the light shaft and the emission characteristic of the light source.

In the variants Fig. 7 and Fig. 8, a reflector surrounding the light source directs the light emitted by the light source so that the light can not leave the light well directly through the gaps 22 and 23, respectively. Again, the shaped of the conductor 14a reflector in its shape to the shape of the light shaft and radiation characteristic

be adapted to the light source.

2aAPR 1982 * 0047 V

Claims (6)

He is entitled to claim 1. Light emitter displays with variable switching voltages and brightness control, characterized in that one or more light emitting chips with
each one and / or an integrated constant current generator and / or voltage-dependent multivibrator and / or other the constant current and / or
a pulse-driving circuit-guaranteeing arrangements, too
a constructive unit can be integrated in a common housing. 2. Light emitter display according to item 1, characterized in that the integrated circuit arrangements have dynamic and / or static brightness controls. 3. Light emitter display according to item 1, characterized in that the integrated circuit arrangements are made in the same material as the light emitting chips. 4. Light emitter display according to item 1, characterized in that the integrated circuit arrangement on the same substrates as the Light emitter chips are mounted. 5. Light emitter display according to item 1, characterized in that a
Brightness control, control of the height of the constant current and the light color is provided and the corresponding encoders are integrated. -6. Light emitter displays according to item 1, characterized in that the Lichtend tterchips are placed on Mesahügeln or troughs. For this JL pages drawings