SK159398A3 - Control circuit for recording the actuation of an optical key - Google Patents

Abstract

The description relates to a control circuit for recording the actuation of an optical key, in which there is a light-sensitive diode operated in open circuit as a key actuation sensor. A microprocessor circuit monitors the no-load voltage of the diode to differentiate an actuation of the optical key from variations in the brightness of the ambient light. The invention is characterized by an easily producible voltage-time-conversion process for monitoring the no-load voltage. To this end, there is a capacitor connected to the diode which assumes a load operating status corresponding to the no-load voltage of the diode and can be discharged in a discharge operating status via a discharge resistor, where the microprocessor circuit has a high-resistance input port connected to the capacitor to monitor the capacitor discharge and, as a measure of the no-load voltage, determines the time elapsing until the voltage at the input port during the capacitor discharge process reaches a predetermined input port switching threshold.

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a control circuit for registering an optical button control in which the light-sensitive diode, operating in the open-circuit voltage generator mode, is assigned as a button control sensor to a light-transmitting button surface. a microprocessor circuit with voltage control means for controlling the diode voltage, and wherein the microprocessor circuit is configured to evaluate the diode voltage information provided by the voltage control means to distinguish the operation of the optical button from the variation of ambient light brightness.

BACKGROUND OF THE INVENTION

For prior art, reference is made to DE 43 36 669 C1, which relates to an input field with logarithmic optical buttons. In this input field, individual control surfaces are assigned optoelectronic control sensors in response to changes in brightness that occur when a finger is placed on the control surface. Photodiodes or light-emitting diodes are used as optical control sensors and are operated as photoelements in idle mode. The diodes produce an output voltage (no-load voltage) that increases approximately logarithmic depending on the incident luminous flux. Such control sensors thus provide an output signal whose amplitude changes relatively little with variations in the intensity of the incident light. Thus, even large changes in ambient brightness do not lead to large changes in the output signal. Thus, it is possible that by rapidly changing the brightness of the incident light, such as typically occurs when a finger is placed on the control surface, there will be a greater time change in the output signal assigned to the control sensor than a larger, but longer time span of the illumination intensity. The evaluation unit connected to the diodes ensures a corresponding distinction

- fast changes, even at a smaller amplitude, from slow changes at a large amplitude, so that it can distinguish the push of a button from the fluctuation of the ambient brightness.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a reliably operating control circuit of this kind which can be realized with less demanding wiring.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The present invention relates to a control circuit for registering an optical button control in which the light-sensitive diode, operated in the open-circuit voltage generator mode, is used as a button control sensor in the form of a light-transmitting button surface. the circuit comprises a microprocessor circuit with voltage control means for checking the diode voltage, and the microprocessor circuit is equipped to evaluate the diode voltage information supplied by the voltage control means to distinguish the pressing of the optical button from the variation in ambient light brightness, the control circuit includes a diode-coupled capacitor which, in the control state of the control circuit, acquires a charge state corresponding to the idle voltage of the diode, and which in the state of the control circuit can be discharged via a discharge resistor, the microprocessor circuit ( 9c) has a high-impedance input port, coupled to the junction point between the diode and the capacitor, to control capacitor discharge, and is equipped to measure, as a measure of the no-load voltage on the diode, the time elapsed while the input port voltage during the capacitor discharge process does not reach the predetermined switching threshold voltage of the input port.

The diode is expediently arranged in a housing with a light-transmitting aperture assigned to the manual input button surface, wherein the diode acts as a photoelement and the control circuit records the diode voltage on the diode, depending on the intensity of the light received by the diode to register a sudden cover, changing the light passage to the diode as a manual data entry process.

The diode thus serves as a logarithmic optical button, the basic principle of which is known from DE 43 36 669 C1.

According to a particularly preferred embodiment, the anode-side diode is coupled to the first output port of the microprocessor circuit and the cathode side via a capacitor with an H-potential terminal, the diode is further coupled at the cathode side via a discharge resistor to the second output port and another resistor. with an input port, wherein the first output port has a defined H-potential in the charging state and is switched to a high ohmic three-state connection in the discharge state, and the second output port is switched to a high ohm three-state connection and a Lpotential defined in the discharge state; the microprocessor circuit in the discharging state as a measure of the no-load voltage on the diode measures the time that elapses until the voltage on the high ohmic input port drops to the switching threshold voltage of the input port, which interprets the microprocessor circuit as a transition from H-level to L-level .

The control circuit according to the invention for registering the control of the optical button is characterized in particular by a very simple voltage-time conversion method for checking the idle voltage at the diode and thus for controlling the control of the button, and the control circuit according to the invention requires little wiring.

The invention will be explained in more detail below with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1a shows a partially schematic block diagram of a first exemplary embodiment of a control circuit according to the present invention operable as a circuit for transmitting and receiving data.

Fig. 1b is a status table showing how certain control circuit terminals will be controlled by the microprocessor circuit in various operating states.

Fig. 1c is a voltage-time diagram to illustrate the operation of the circuit of FIG. 1a in the push-button input operating mode.

Fig. 2 shows a variant of the control circuit of FIG. 1a.

-4Obr. 3 illustrates a particular example of use for a circuit for transmitting and receiving data with a control circuit according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1a is a partially schematic block diagram of a first exemplary embodiment of a control circuit according to the present invention operable as a data transmission and reception circuit.

The data transmission and reception circuit 1 comprises, for the optical exchange of data, an apparatus not shown in FIG. 1a, a conventional infrared light-emitting diode 5, which in the circuit 1 for transmitting and receiving data is used both for transmitting and receiving optical data in half-duplex operation.

The light-emitting diode 5 is connected by its anode to the output port 7 of the microprocessor circuit 9.

The cathode of the light-emitting diode 5 is connected via a first resistor H, for example 1.5 ΜΩ, to the output port 13 of the microprocessor circuit 9, which has an H-potential in the optical data transmission mode and in the optical data reception mode. , with port 17 for bi-directional data transfer of microprocessor circuit 9.

The output port 13 can be switched by a microprocessor circuit 9 to a high ohmic three-state connection so that the output 13 is quasi-electrically disconnected in this state.

The data transmission and reception circuit 1 is arranged for asynchronous, bit-series data transmission in half-duplex operation, the microprocessor circuit 9 controlling the data transmission and reception operation according to the standard serial data transmission protocol.

In FIG. 1b shows a table in which the electrical states and the electrical states are shown in FIG. levels of terminals A, B, C, D depending on the current operating state of the data transmission and reception circuit 1 of FIG. 1a.

-5 In the data transmission mode, the microprocessor circuit 9 sets the output port 7 so that at the terminal B there is an H-level. The microprocessor circuit 9 then sends a bit sequence corresponding to the signal to be transmitted via the terminal A of the data transfer port 17. The level at the terminal A varies, corresponding to the bit sequence, between H (= Mark) and L (= Space). This results in a corresponding modulation of the brightness of the light-emitting diode 5, whereby the light-emitting diode 5 is operated in the forward direction and correspondingly illuminates when the A-level is output A, while the light-emitting diode 5 goes off when the A-level is output. The light-emitting diode 5 thus transmits an optical data signal corresponding to a sequence of bits transmitted through the output A of the microprocessor circuit 9.

The signal transmitted by the light emitting diode 5 receives in the example of FIG. 1a, a second apparatus (not shown) which acts as a communication partner of the circuit 1. for transmitting and receiving data according to a corresponding data transmission protocol.

To turn on the data-receiving mode, the microprocessor circuit 9 sets the LED 5 anode through port B of port 7 to the L-level to bias the LED 5 that is coupled to the Potential, in the reverse direction, and the tri-state the buffered port 17 for data transfer is switched by the microprocessor 9 for receiving the data, and terminal A now forms a very high ohmic input connection.

The upstream resistor 11 has a relatively high resistance value, for example 1.5 ΜΩ. The light-emitting diode 5, in the data-receiving mode operated by the microprocessor circuit 9 as a photodiode, has a (very small) reverse current in the reverse direction, which strongly depends on the intensity of the light incident on the light-emitting diode. When receiving an optical data signal in the form of a light / dark bit sequence, the reverse current of the diode 5 is correspondingly modulated so that a corresponding electrical data signal appears at the high ohmic terminal A of the bidirectional data port 17 connected to the cathode of the diode 5. which registers the microprocessor circuit 9 as a received data signal.

The apparatus used as the optical communication partner of the data transmission and reception circuit 1 may also be equipped with a data transmission and reception circuit as shown in FIG. 1a, but marked alternatively by 1

The apparatus could be equipped in conventional manner with separate optical elements for transmitting and receiving optical data signals.

The light-emitting diode 5 is used not only for bi-directional intermittent data communication, but also in multiplex operation as a control sensor. a logarithmic button known per se from the German patent DE 43 36 669 C1. Such a pushbutton can serve, for example, to switch the operating mode of the data display device 19 connected to the microprocessor circuit 9 by manually pressing the pushbutton.

Pressing the button manually in the embodiment of FIG. 1a means that the operator sheds a finger 21 with the finger in the operating area 23, transmitting light to the diode 5. The operating area 23 is located on the wall of the housing indicated by 25.

In addition to the types of operation of Transmitting Data and Receiving Data, as already shown in FIG. 1a and FIG. 1b, the circuit of FIG. 1a shows a push-button mode in which the light-emitting diode 5 operates in idle mode and its idle voltage is detected, which is approximately proportional to the logarithm of the light intensity incident on the light-emitting diode.

The no-load voltage measurement on the diode 5b according to the present invention is carried out in a simple voltage-time conversion method. In the button input mode, in the first step, the capacitor 31 is charged by a light emitting diode 5, operated in the idle voltage generator mode, in a few ms to the idle voltage of the diode. In a second step, the capacitor 31 is discharged and the time is measured until the voltage on the capacitor drops below a certain switching threshold.

In the embodiment of FIG. 1a, the respective capacitor 31 is connected between the cathode of the light-emitting diode 5 and the terminal D of the three-state output port 33 of the control circuit 9.

The microprocessor circuit 9 controls the various operating states of the circuit for transmitting and receiving data in multiplexed traffic.

Referring to the status table in FIG. 1b, the terminal D of port 33 is in both the data transmission mode and the data reception mode in the extremely high ohmic three-state TS connection. Due to the external wiring of the microprocessor circuit 9 to

7 means that the output port 33 is electrically disconnected. The other terminals A, B and C are set in the data transmission mode by the microprocessor circuit 9, as already mentioned, with the capacitor 31 in FIG. 1a does not affect the operation of data transmission and data reception, as terminal D is electrically disconnected.

As already indicated, the button input mode is divided into two steps. These are the steps of charging the capacitor and discharging the capacitor, as well as measuring the discharge time.

In a first step, terminals A and C are in a high ohmic three-state TS connection, while terminals B and D have an H-level, so that diode 5 is in idle voltage generator mode. The diode 5 now charges the capacitor 31 to its no-load voltage, depending on the intensity of the incident light, as in the example of FIG. 1a referenced to the H-potential (Vcc) (terminals B and D to the H-potential).

In FIG. 1c is a qualitative representation of the voltage waveform to be registered at terminal A of port 17 for bidirectional data transmission, in a voltage diagram for a capacitor charging step and a discharge step, which will be explained further.

The curve X _L in FIG. 1c shows the voltage waveform at terminal A in the event that the photoelement diode 5 receives little light when the window 21 of the operating surface 23 is fingered. The curve Y _L indicates the voltage curve at the terminal A in case a greater amount of light reaches the diode 5, which is normally the case when the window 21 is not shaded from the outside.

The voltage U which is set at terminal A after a predetermined charging time t _L corresponds to the value (Vcc - U _o ), where Vcc is the voltage of the level (operating voltage) and U _D is the light-emitting diode voltage, on the diode. In the case of a smaller light incidence (curve X _L ), the open-circuit voltage U _{D is} less than in the case of a stronger light incidence (curve Y _L ). The L-potential is greater than the voltage at terminal A after the charging time t _L in the case of a weaker light incident than in the case of a stronger light incident.

The microprocessor circuit 9 terminates the capacitor charging step after a predetermined time t _L by switching the output port 7 (terminal B) to the high ohmic three-state TS connection and setting terminal C to the Level state. This will start the discharge capacitor step, while discharging

The capacitor 31 is implemented through a high ohmic first resistor H and a terminal C to ground. The microprocessor circuit 9 measures the time t _E which elapses until the voltage at terminal A drops to the switching threshold voltage of port 17, which is in the high ohmic receiving state TS. The switching threshold level of port 17 is shown in FIG. 1c designated U _{H. L} If the voltage at terminal A falls below this level, the microprocessor circuit 9 interprets this as a transition from H to L.

The voltage curve at terminal A during the capacitor discharge step is shown in FIG. 1c is shown by the X _E curve for low light impact (optical button depressed) - and the Y _E curve for stronger light impact (optical button not depressed).

Discharge curve X _E resp. Y _E pursues the relationship with a very good approximation

U (t) = (Vcc-U _D ) x exp (-t / x).

where they mean:

U (t) voltage at terminal A,

Vcc H-level voltage,

U _D diode voltage, τ time constant.

With a capacitor 31 of 1 nF and a discharge resistor H of 1.5 ΜΩ, the time constant τ reaches 1.5 ms.

As clearly seen in FIG. 1c, the curve Y _E falls below the switching threshold voltage U _{H. L} rather than the curve X _E , so that the microprocessor circuit 9, by measuring the time, indirectly obtains information about the state of the diode illumination 5. Because the logarithmic optical button is only a relatively fast change (<1 s) and not absolute diode voltage values. 5, this very simple voltage conversion in order to distinguish between the button depressed and the non-depressed states is sufficient.

Now -9Ak microprocessor circuit 9 for two successive measurement cycles, determines that the time t _e after the discharge of the capacitor to drop below the _{UH. L} in the last measurement cycle performed was longer than in the previous measurement cycle, and by a certain minimum difference from the previous measurement cycle, this interprets it as pressing the button 21, 23 and switches the display mode of the digital display device 19.

The previously described principle of realization and control of a logarithmic optical button may be extended to an optical button array with multiple buttons, as schematically indicated in FIG. Second

The embodiment of FIG. 2 differs from the example of FIG. 1a, in that a plurality of light-emitting diodes 5c are provided in place of a single light-emitting diode 5, each of which is associated with a separate button (not shown) of the operating button field. Mark 35 in FIG. 2, a multiplexing device, which is set by the microprocessor circuit 9c by a control signal transmitted to the terminal E, selectively connects one of the anode-side light-emitting diodes 5c to the connection line 37 connected to the output terminal B of the microprocessor circuit 9c. a cathode with a coupling point 39 of the capacitor 31c and resistors 11c, 15c. The circuit of FIG. 2 operates with respect to the diode 5c just connected to the measuring operation, as in the embodiment of FIG. 1a. The individual diodes 5c are queried at regular intervals.

Although in the embodiment of FIG. 2 each of the light-emitting diodes 5c can be used both as a logarithmic optical button and as an optical transmitting and receiving element in the manner described. 2, in the context of the present invention, alternatively, the diodes 5c may be used exclusively as control sensors for optical buttons. In this case, the data transmitting mode and the data receiving mode may be omitted, so that the circuit is formed only as a button control.

In FIG. 3 illustrates an example of use for a circuit for transmitting and receiving data of the kind described above. Shown is an electronic consumption meter 52 (heating cost allocator), fixedly mounted on a heater 50 having an infrared optocommunication interface in the form of a circuit for transmitting and receiving data, via an optocommunication interface

The measured values for the consumption of the heater can be read from the consumption measuring device 52. For this purpose, a portable reader 54 with an optical head 56 is provided, which has, for example, a phototransistor as an optical receiving element and as a light emitting element for communicating with the apparatus 52. For the transmission of data between the optocommunication interface of the apparatus 52 and the optical head 56, it is applied to the window 21d of the apparatus 52, with a light emitting diode of the circuit being provided behind the window 21d. It is also possible to transmit data from the reader 54 via the optical head 56 to the consumption meter 52, for example, readout times and / or parameter values that specify a heater class and the like, and are memorized in the apparatus 52. receiving data in the apparatus 52 also takes on tasks related to measuring consumption and evaluating the data.

The digital display device 19d of the apparatus 52 can be manually switched between several types of operational display. For this purpose, the light-emitting diode behind the window 21d of the device 52 serves as a button control sensor in the manner described above. The button in this sense is actuated when, for example, the window 21d is shaded with a finger.

In a manner similar to the embodiment of FIG. 3, the circuit for transmitting and receiving data of the kind described may also be used, for example, in other electronic consumption meters, such as water meters, heat consumption meters, gas meters, electricity meters, etc. This list is by no means exhaustive.

Claims (2)

PATENT CLAIMS A control circuit for registering an optical button control, in which the light-sensitive diode (5; 5c), operated in the open-circuit voltage generator mode, is used as a light-actuating push-button button (21, 23) which is light-transmitting and externally shield the finger before the light input, the control circuit having a microprocessor circuit (9; 9c) with voltage control means for checking the idle voltage on the diode (5; 5c), and wherein the microprocessor circuit (9; 9c) is equipped to evaluate the no-load voltage information on the diode (5; 5c) provided by the voltage control means to distinguish the pressing of the optical button from the variation of the ambient light brightness, characterized in that it comprises a capacitor (31; 31c) connected to the diode (5; 5c) ), which in the state of charge of the control circuit acquires a state of charge corresponding to the idle voltage of the diode (5; 5c), and which in the state of discharge of the control o the circuit can be discharged via a discharge resistor (11; 11c), the microprocessor circuit (9; 9c) has a high-impedance input port (terminal A) coupled to the junction point between the diode (5; 5c) and the capacitor (31; 31c) to control the capacitor discharge, and is provided to provide a no-load voltage measure on the diode (5; 5c) measure the time that elapses until the input port voltage (terminal A) during the capacitor discharge process reaches a predetermined switching threshold voltage of the input port (terminal A). Control circuit according to claim 1, characterized in that the diode (5; 5c) is connected at the anode side to the first output port (terminal B) of the microprocessor circuit and at the cathode side via a capacitor (31; 31c) to the terminal (D). with H-potential, and that the diode (5; 5c) is further coupled on the cathode side via a discharge resistor (11; 11c) to a second output port (terminal C) and via another resistor (15b; 15c) to an input port (terminal A) ), wherein the first output port (terminal B) has a H-potential in the charging state and is switched to a high ohmic three-state connection in the discharge state, while the second output port (terminal C) is switched to a high ohmic three-state connection The discharge state has a defined L-potential, and wherein the microprocessor circuit in the discharge state measures the idle voltage on the diode (5; 5c) measures the time that elapses until the voltage on the high ohmic input port (terminal A) drops to the switching threshold voltage of the input port. , the drop below which the microprocessor circuit interprets as a transition from the H-level to the L-level.