SK284254B6 - Data sender and receiver arrangement - 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

The invention relates to a circuit for transmitting and receiving data for transmitting and receiving optical data signals, in which at least one light-emitting diode (light-emitting diode) is an optoelectronic transmitting element for converting an electrical data signal into an optical data signal and for transmitting the optical data signal to a control circuit providing in the data transmission mode a circuit for transmitting and receiving data an electrical data signal.

BACKGROUND OF THE INVENTION

Such data transmission and reception circuits are used, for example, in optocoupler circuits for bidirectional optical data transmission, while in conventional optical data transmission interfaces, in addition to the light emitting diode acting as an optical transmitter, a photodiode or phototransistor is still used as the optical receiving element. In a conventional optocoupler circuit, two circuits for transmitting and receiving data, each having a light emitting diode and a phototransistor, respectively, are required to form a bidirectional optical communication path. photodiode for receiving.

Circuits for transmitting and receiving data of the aforementioned type are used, for example, in electronic heaters of heating costs which are permanently mounted on the respective heating element in order to measure consumption values. The measured consumption values can be read by a portable reading device, the reading being carried out by optical transmission of data from the heating cost distributor to the reading device. On the other hand, data such as reading times and the like can also be transferred from the reading device to the heating cost allocator.

DE 30 35 944 A1 discloses an optoelectronic semiconductor arrangement, namely a signal arrangement with diodes fulfilling the function of visual signal elements. The light intensity of the light emitting diode is regulated in order to achieve an improvement in the contrast, respectively. so that the radiation intensity always adapts to the light intensity of the surroundings. To this end, it is proposed in DE 30 35 944 A1 to operate the light-emitting diodes at intervals in which they are not switched on to emit light and thus operate as photovoltaic elements and thus as sensors in the radiation control circuit. Said diode is also used as an analogue sensor for measuring the ambient light.

In the prior art, further reference is made to EP 0 651 509 A or DE 43 36 669 C1 relating to an input field with "logarithmic optical buttons". At the input field, optoelectronic control sensors are assigned to each control surface, which respond 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 used as photoelements when idling. The diodes create a no-load voltage that increases approximately logarithmic depending on the incident luminous flux. Such control sensors therefore provide an output signal whose amplitude changes relatively little with variation in the intensity of incident light. Therefore, even large changes in ambient brightness do not lead to large changes in the output signal. The diode-coupled evaluation unit provides appropriate distinction between fast changes and slow changes in light intensity, in order to distinguish the push of a button from the variation of the ambient brightness.

It is an object of the present invention to simplify a circuit for transmitting and receiving data of this type.

SUMMARY OF THE INVENTION

To solve this problem, according to the present invention, it is proposed that the light emitting diode in the data receive mode of the data transmitting and receiving circuit be controlled by the control circuit in such a way as to act as an optoelectronic data receiving element to convert the received optical data signal into an electric data signal. which registers the control circuit, the control circuit imparting a backward bias to the light-emitting diode and detecting from the back-up light-emitting diode, and thereby the light intensity incident on the light-emitting diode, a dependent electrical signal in a manner that differentiates the binary states of the optical data signal received .

Accordingly, the present invention is based on the idea of uniting a transceiver and a transceiver element for transmitting and receiving data of this kind into one optoelectronic component, which will be controlled by the control circuit alternately as a transceiver and as a receive element, depending on the respective operating mode (transmit or receive). the light-emitting diode in the data-receiving mode is operated as a photodiode in violation of its own designation. In particular, the optoelectronic component may be a conventional light emitting diode, such as an IR light emitting diode or a light emitting diode in the visible region. To date, it has not been found and practiced that light-emitting diodes whose electro-optic mechanism of action is based on the choice of basic semiconductor material and special doping for optimum light emission have a photocurrent sensitivity sufficient to produce differences in I / O contrast intensity, common in optical data transmission, reliably distinguished.

Thus, in a data transmission and reception circuit according to the present invention, the phototransistor common in prior art circuits of this kind eliminates data reception, which simplifies and reduces the overall cost of the circuit.

If, in a data transmission and reception circuit according to the present invention, data is to be transmitted through only one serial data transmission channel, only half-duplex operation is possible using a single light emitting diode as a transmitting and receiving element. However, this is not a limitation in many applications and protocols.

Surprisingly, the exemplary scattering measurements have shown that light-sensitivity of light-emitting diodes is a systematic and reproducible property, so that commercial light-emitting diodes do not need to be tested first for usability in the data transmission and reception circuit of the present invention.

The use of a diode as both a receiving element and a transmitting element offers, due to the large spatial angle at which light can be transmitted and received, the further advantage that in an optical communication path from two optically communicating data transmitting and receiving circuits according to the invention it depends on the exact setting of the diodes opposite to each other, as is the case with conventional systems with separate optoelectronic components for transmission and reception.

In one preferred embodiment of the invention, the cathode side of the cathode is coupled via a resistor to the first, H-potential having the output terminal of the control circuit, and the anode to the second output terminal of the control circuit, which has the H-po data transmission mode.

The control circuit has a data output terminal coupled to the diode cathode for transmitting the electrical data signal in data transmission mode. The control circuit controls the transmission direction of the optical data transmission via the level of the second output terminal present at the diode anode. If the second output terminal is L-level, the diode is reversed in the reverse direction, and the data transmitting and receiving circuit is ready to receive. In the data transmission mode, the diode will control the H-potential from the second output terminal by the anode, and then, depending on the data signal transmitted through the data output terminal, the potential on the diode cathode will be modulated, resulting in corresponding modulation of the LED brightness. the diode emits a corresponding optical data signal.

If the electrical data signal transmitted through the control circuit data output terminal consists of a sequence of H / L bits, the diode transmits a light signal when the current state of the electrical data signal is L, and the diode goes off when the current state of the data signal is H. and preferably a resistor is connected to the data output terminal of the control circuit.

For electrical registration of the received optical data, the high ohmic control circuit input terminal is coupled to the diode cathode.

In a particularly preferred embodiment, the control circuit has a bidirectional data transmission port through which in the data transmission mode it transmits an electrical data output signal and through which in the data reception mode it detects a dependent voltage of the light emitting diode as an input signal. In the data receiving mode, a bidirectional port for transmitting data in a very high ohmic state is connected to the light-emitting cathode via the resistor.

The control circuit preferably comprises a microprocessor for controlling the operation of transmitting and receiving data.

Suitably, the control circuit has a serial interface for bidirectional asynchronous data transfer via a diode in half-duplex operation, whereby the data transfer can be performed according to a standard protocol.

According to a further embodiment of the invention, the diode is provided in a housing with a light-transmitting aperture towards the diode associated with the manual data input button, wherein the data transmitting and receiving circuit is further operable in the data input mode under control of the control circuit. a button in which the diode in the idle state acts as a photoelectric element and the control circuit senses the light-emitted light intensity received from the light received by the diode so that the sudden shading of the opening in the housing changing light leakage to the diode is registered as a manual data input process.

Thus, the diode, in the data entry mode of a button switched on in multiplex operation by the control circuit, serves as a logarithmic optical button, as is known in principle from DE 43 36 669 C1.

According to a preferred embodiment, in the push-button data input mode, the diode is controlled by the control circuit in such a way that the anode side is connected to the H-potential and the cathode side with the high ohmic input of the analogue digital converter of the control circuit, the control circuit having a microprocessor for evaluating the information digital converter. Via an analog-to-digital converter, the microprocessor senses the no-load voltage of the diodes based on the H-potential (Vcc). If the microprocessor detects that the idle voltage of the diode has dropped sharply at a certain minimum rate of change when creating the difference of two successive voltage readings, this will be interpreted as pressing a logarithmic optical button.

According to a further embodiment of the present invention, the data transmission and reception circuit is formed as an optical communication interface of the measuring apparatus, which is adapted to optically exchange data with the second instrument, wherein the second instrument may also have a data transmission and reception circuit as optical communication interface. invention.

The measuring device may be an electronic consumption meter to be installed at the point of consumption, such as a heating cost allocator, water meter, heat meter, gas meter, electricity meter or the like, the second meter being a portable reading device that can exchange data with consumption meter.

If the power meter transmit and receive circuitry is also designed for push button data input mode, and the push button data input diode acts as a push button sensor, it may be arranged to press different logarithmic optical button switches to display different types of power meter display.

According to one variant of the embodiment with a logarithmic optical button, it is proposed that a capacitor be connected to the diode, which in the state of charge of the control circuit in the data input mode is pushed to a state corresponding to the idle voltage of the diode. the push-button data input mode can discharge via a discharge resistor, the control circuit having a high-ohm input port for monitoring the capacitor discharge, and is configured to measure the time that elapses until the voltage at the diode the input port during the capacitor discharge process does not reach the specified switching threshold voltage of the input port.

According to a preferred embodiment of the variant, the anode-side diode is connected to the first output port of the control circuit and the cathode side via an H-potential capacitor, the diode is further connected to the second output port on the cathode side via a discharge 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-position state in the discharge state, and the second output port is switched to a high ohm three-position state and wherein the control circuit in the discharging state as a measure of the idle voltage of 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, interpreting the drop below which the microprocessor circuit interprets as transition from Wall to L-level.

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

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1a shows, partly in block diagram, a circuit diagram of a first embodiment of a data transmission and reception circuit according to the present invention.

Fig. Ib is a status table from which it can be seen how the particular control circuit terminals are controlled by the control circuit in different operating states.

Fig. 2a shows, partly in block diagram, a circuit diagram of a second embodiment of a data transmission and reception circuit according to the present invention with an integrated optical button.

Fig. 2b shows the circuit of FIG. 2a shows a status table showing how the different control circuit terminals are controlled by the control circuit in different operating states.

Fig. 3a shows, partially in block diagram, a circuit diagram of a third embodiment of the present invention with an integrated optical button.

Fig. 3b shows the circuit of FIG. 3a shows a state diagram showing how the particular control circuit terminals are controlled by the control circuit in different operating states.

Fig. 3c is a voltage-time diagram for illuminating the mode of operation of the circuit of FIG. 3a in data entry mode with the button.

Fig. 4 illustrates a control circuit for registering optical button presses.

Fig. 5 illustrates a particular example of use for a circuit for transmitting and receiving data according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1a shows, partially in block diagram, a circuit diagram of a first exemplary embodiment of a data transmission and reception circuit according to the present invention.

The circuit for transmitting and receiving data comprises for optically exchanging data with the apparatus; 1a, indicated by 3, a conventional infrared light-emitting diode 5, which is used in the data transmitting and receiving circuit 1 for both transmitting and receiving optical data in half-duplex operation.

The light-emitting diode 5 is connected with its anode to the output port 7 of the programmable control circuit 9, which is preferably a microprocessor circuit.

The cathode of the light-emitting diode 5 is connected via a first resistor 11, with a resistance of, for example, 1.5 ΜΩ, to a Vcc terminal 13 with the H-potential of the control circuit 9, and through a second resistor 15 with a resistance of 680 680, to a bidirectional port 17 control circuit data 9.

The data transmission and reception circuit 1 is adapted for asynchronous, serial data transmission by bit in half-duplex operation, the control circuit 9 controlling the transmission and reception process according to a standard serial data transmission protocol.

In FIG. Ib is a table in which the electrical states, respectively, are shown. Levels A and B of port 17, resp. 7, depending on the current operating state of the data transmission and reception circuit 1 of FIG. Ia.

In data transmission mode, the control circuit 9 controls the output port 7 so that the terminal B has an H-level. Via terminal A of data transfer port 17, the control circuit 9 then passes a bit sequence corresponding to the signal to be transmitted, the level at terminal A varying according 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, wherein the light-emitting diode 5 is operated in the forward direction and lights up accordingly when the A-level is at the L terminal, opposite the light-emitting diode 5 goes off when the A-level is on the A-terminal. thus transmitting an optical data signal that corresponds to a sequence of bits transmitted through terminal A of the control circuit 9.

The signal in the example of FIG. 1a, it receives a second apparatus 3 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 receive mode, the control circuit 9 sets the anode of the light-emitting diode 5 through port B of port 7 to L, so that the light-emitting diode 5 at the cathode side connected to the first resistor by H-potential is biased in reverse direction. a bi-directional buffered data transfer port 17 for receiving data, and terminal A now forms a very high ohmic input terminal.

The resistor 11 has a relatively high resistance, for example 1.5 ΜΩ. The light-emitting diode 5, operated by the control circuit 9 in the data-receiving mode, operated 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 diode 5 current is appropriately modulated so that a corresponding electrical data signal appears on the high ohmic pin A of the bidirectional data transfer port 17 connected to the cathode 5 via the second resistor 15. which registers the control circuit 9 as a received data signal.

The apparatus 3, shown as the optical communication partner of the data transmission and reception circuit 1 according to the present invention, may also be equipped with a data transmission and reception circuit as shown in FIG. However, alternatively, the apparatus 3 could be equipped in conventional manner with separate optical elements for transmitting and receiving optical data signals.

In FIG. 2a shows, partially in block diagram, a circuit diagram of a second embodiment of the invention.

The circuit elements of FIG. 2a, which correspond to the elements of FIG. 1a, are always designated with the same reference numerals and the letter a added, so that the description of the embodiment according to FIG. 1a, and the following explanations of the embodiment of FIG. 2a may in principle be limited to differences from the first embodiment.

The embodiment of FIG. 2a represents an extension to the first embodiment in the sense that the light-emitting diode 5a is used not only for bidirectional occasional data communication, but also in multiplex operation as a so-called compression sensor. a logarithmic optical button known per se from the German patent DE 43 36 669 C1. Such a button may serve, for example, to turn on a certain type of display on the data display device 19 connected to the control circuit 9a by manually pressing the button.

In the exemplary embodiment shown in FIG. 2a, that the operator is finger-closing the window in the control surface 23, indicated as 21, transmitting light to the diode 5a. The control surface 23 is located on the wall of the housing marked 25.

In addition to the mode of operation of "transmitting data" and "receiving data", as already mentioned with reference to FIG. 1a, the circuit of FIG. 2a has a push-button data input mode, in that the light-emitting diode 5a is operated at idle and its idle voltage is detected, which is almost proportional to the logarithm of the light intensity incident on the light-emitting diode.

In contrast to the embodiment of FIG. 1a, the light-emitting diode 5a is connected via an upstream resistor 11a on the cathode side to an output terminal 13a which can be switched by the control circuit 9a to a high ohmic three-position state, so that the output 13a is electrically quasi-disconnected in this state.

Fig. 2b shows a table showing the electrical states of the terminals A, B and C of ports 17a, 7a and 7a, respectively. 13a, depending on the respective operating state of the circuit 1a.

With respect to the operating modes "data transmission mode" and "data reception mode", the ratios are the same as in the first embodiment of FIG. 1a (cf. the table in Fig. 1b). In push-button data input mode, terminals A and C have a high ohmic three-position state TS and terminal B a level H, which means that the light-emitting diode 5a is in a no-load state.

For the no-load voltage sensing, the control circuit 9a, preferably designed as a microprocessor circuit, has an analog-to-digital converter 27 with a very high ohmic input 29 which is electrically connected to the light-emitting diode 5a via the second resistor 15a. In this connection, the (negative) voltage is measured relative to the H-potential (Vcc). As can be seen immediately in FIG. 2a, in this way a very simple voltage measurement connection is obtained.

In push button data input mode, the control circuit 9a periodically detects the signal values obtained at the output of the analog-to-digital converter 27 and checks whether the newly acquired signal value differs by more than a predetermined difference from the previous signal value. If this is the case, the control circuit 9a will consider this as pressing the logarithmic optical button 21, 23, and then the control circuit 9a will switch the display mode of the device 19 to digital display.

The sensing and evaluation of the difference of two consecutive voltage values at the output of the analog-to-digital converter 27 is to ensure that rapid changes in the brightness of light incident on the light emitting diode 21, such as typically occur when a finger is placed on the control surface 23, distinguished from slower fluctuations in ambient light intensity.

In FIG. 3a is a block diagram of another embodiment of the present invention.

The elements of FIG. 3a corresponding to the elements already described with reference to FIG. 1a and 2a are designated respectively with the same reference numerals and the letter b added, so as to avoid repetition, reference is made to the embodiments 1 and 2.

In the embodiment of FIG. 3a, the light-emitting diode 5b is used in the push button data input mode, as in the second exemplary embodiment, as a logarithmic optical button push sensor.

In contrast to the second embodiment of FIG. 2a, however, no analog-to-digital converter is required to sense the no-load voltage of the diode 5b. The open-circuit voltage measurement of the diode 5b in the embodiment according to FIG. 3a performs according to the invention according to a simple voltage-time conversion process. In the data input mode, in the first step, the capacitor 31 is charged by the light emitting diode 5b, which is in the idle voltage generator mode, in a few ms to the idle voltage of the diode. In a second step, the capacitor is discharged and the time is measured until the voltage on the capacitor drops below the switching threshold.

In the embodiment of FIG. 3a, the respective capacitor 31 is connected between the light-emitting cathode 5b and the outlet D of the three-position output port 33 of the control circuit 9b.

As in the first and second exemplary embodiments, the control circuit 9b, preferably designed as a microprocessor circuit, controls the various operating states of the circuit for transmitting and receiving data in multiplexed traffic.

Referring to the status table in FIG. 3b, terminal D of port 33 is in both data transmission mode and data reception mode in an extremely high ohmic three-position state TS. With respect to the external wiring of the control circuit 9b, this means that the output port 33 is electrically disconnected. The other terminals A, B and C will control the control circuit 9b in the data transmission mode and in the data reception mode in the same way as with reference to FIG. 1 and 2 have been explained in the description of the first two exemplary embodiments. Therefore, in the data transmission mode and in the data reception mode, the circuit of FIG. 3a as the circuit of FIG. 2a, the capacitor 31 in FIG. 3a does not affect the process of transmitting data and receiving data since terminal D is electrically disconnected.

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

In a first step, terminals A and C are in a high ohmic three-position state TS, while terminals B and D have an H-level, so that diode 5b is switched to idle voltage generator mode. The diode 5b now charges the capacitor 31 to its no-load voltage, depending on the intensity of the incident light, which in the example of FIG. 3a refers to the H-potential (Vcc) (terminals B and D at the H-potential).

In FIG. 3c is a qualitative representation of the voltage waveform to be registered at the A terminal of the bidirectional data transmission port, in the voltage-time diagram for the capacitor charging step and for the discharge step still to be explained.

The curve X _L in FIG. 3c shows the voltage waveform at terminal A in the event that the photoconductor diode 5b receives little light, which is the case when the window 21b of the control surface 23b is shaded with a finger. The curve Y _L indicates the voltage waveform at terminal A in the event that a greater amount of light reaches the diode 5b, which is normally the case when the window 21b is not shaded from the outside.

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

The control circuit 9b terminates the capacitor charging step after the set time t _{L has} elapsed by switching the output port 7b (terminal B) to a high ohmic three-position state TS and switching terminal C to an L-level state. This initiates the capacitor discharge step, the discharge of the capacitor 31 being effected via the high ohmic first resistor 11b and the outlet C to the chassis. The control circuit 9b measures the time t _E which elapses until the voltage at terminal A drops to the switching threshold voltage of port 17b, which is in the high ohmic TS-state for receiving. The switching threshold level of port 17b is shown in FIG. 3c designated at _H .l · When the voltage at the terminal A falls below the threshold, the control circuit 9b, it will be interpreted as a change from H to L.

The voltage curve at terminal A during the capacitor discharge step is shown in FIG. 3c 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 complies with a very good approximation of the relationship U (t) = (Vcc - U _D ) x exp (-t / r).

SK 284254-6

Here denotes: U (t) voltage at terminal A,

The H-level voltage thing,

U _D diode voltage, τ time constant.

With a capacitor 31 with a capacity of 1 nF and a discharge resistor 11b with a resistance of 1.5 ΜΩ, the time constant τ reaches 1.5 ms.

As clearly seen in FIG. 3c, the curve Y _E is under the switching threshold voltage U _l _hours before the curve X _E, so that the microprocessor circuit 9b obtained by measuring the time indirect information about the status light emitting diodes 5b. Since the logarithmic optical button is only a relatively fast change (<1 s) and not the absolute photovoltaic (diode) values of the diode 5b, this very simple voltage-to-time conversion to distinguish between the "push-button" and "non-push-button" states sufficient.

Now that the microprocessor circuit 9b in two consecutive measurement cycles detects that the capacitor discharge time t _E to drop below U _h .1 in the last measurement cycle performed was longer than the previous measurement cycle, with some smallest difference from the previous measurement cycle. measuring cycle, interprets it as pressing button 21b, 23b and switches the display mode of digital display device 19b.

The previously described principle of realization and tracking of the logarithmic optical button can in particular be extended to an optical button array with multiple buttons, as schematically indicated in FIG. 4th

The embodiment of FIG. 4 differs from the example of FIG. 3a, in that a plurality of light-emitting diodes 5c are used instead of a single light-emitting diode 5b, each of which is assigned to a separate optical button (not shown) of the button control field. Mark 35 in FIG. 4, a multiplexing device, which is controlled by the microprocessor circuit 9c via a control signal transmitted at terminal E, is selected by selectively connecting one of the anode-side light-emitting diodes 5c with the connection line 37 connected to the output terminal B of the microprocessor circuit 9c; the cathode side with the coupling point 39 of the capacitor 31c and the resistors 11c, 15c. The circuit of FIG. 4 operates with respect to the diode 5c connected in the measuring operation, as in the embodiment according to FIG. 3a. The "polling" of the individual diodes 5c takes place at regular time intervals.

In the embodiment of FIG. 4, each of the light-emitting diodes 5c may be used both as a logarithmic optical button and as an optical transceiver element in the manner described.

In FIG. 5 illustrates an example of use for a data transmission and reception circuit according to the present invention. An electronic consumption meter (heating cost distributor) 52 with an infrared optocommunication interface in the form of a data transmission and reception circuit according to the present invention is permanently mounted on the radiator 50, and the consumption data of the radiator and radiator can be read via the optocommunication interface. 52 for measuring consumption. For this purpose, a portable reader 54 with a head-on 56 is provided, which, for example, has a phototransistor as an optical receiving element and a light-emitting diode as an optical transmitting element for communicating with the apparatus 52. For transmitting data between the optocommunication interface of the apparatus 52 and Apparatus 52, wherein a light emitting diode of the data transmission and reception circuit according to the present invention is arranged behind the window 21d. It is also possible to transmit data from the subtraction apparatus 54 via the opto-head 56 to the consumption metering apparatus 52, for example, readout points and / or parameter values that specify a heater class and the like, and stored in the apparatus 52. receiving the data according to the present invention in the apparatus 52 may be a microprocessor that also takes on tasks in terms of evaluating the consumption measurement and the measured values.

The digital display device 19d of the apparatus 52 can be manually switched between multiple modes of operation display. For this purpose, the light-emitting diode behind the window 21d of the device 52 serves as a push-button sensor as described above. Pressing the button in this sense occurs when the window 21d is shaded by a finger, for example.

In a manner similar to the embodiment of FIG. 5, the data transmission and reception circuit according to the present invention may also be used, for example, in other electronic consumption meters, for example water meters, heat quantity meters, gas meters, electricity meters, etc. This list is by no means definitive. The invention can be used wherever bi-directional data transmission is to be performed in half-duplex operation via optoconnection.

Claims (10)

A circuit for transmitting and receiving data for transmitting and receiving optical data signals, wherein the at least one light emitting diode (5, 5a, 5b, 5c) is an optoelectronic transmitter element for converting an electrical data signal into an optical data signal and transmitting an optical data signal. a signal coupled to a control circuit (9, 9a, 9b, 9c), preparing said electrical data signal in the data transmission mode of the data transmission and reception circuit, characterized in that the light-emitting diode (5, 5a, 5b, 5c) is electrically connected at the cathode side to the H-potential terminal (C) and at the anode side to the output (B) of the control circuit (9), which is controlled by the control circuit (9) between H-potential and L-potential, ) is by switching the output (B) to L - potential pre-selectable in the reverse direction, to generate an intensity-dependent light-emitting diode (5, 5a, 5b, 5c) current y of light incident on the light emitting diode (5, 5a, 5b, 5c), wherein the light emitting diode (5, 5a, 5b, 5c) in the data receiving mode of the data receiving and transmitting circuit as an optoelectronic data receiving element is adapted to be transmitted by it of the received optical signal to the electrical signal, and the light-emitting diode (5, 5a, 5b, 5c) is further coupled at the cathode side with the data supply (A) of the control circuit (9, 9a, 9b, 9c) and the control circuit (9, 9a) 9b, 9c) comprises means for recording the voltage dependent on the lightning current of the light emitting diode (5, 5a, 5b, 5c) and associated with the data input (A). Data transmission and reception circuit according to claim 1, characterized in that the light-emitting diode (5, 5a, 5b, 5c) is connected to the terminal (11, 11a, 11b, 11c) on the cathode side (11, 11a, 11b, 11c). C) a control circuit (9, 9a, 9b, 9c) having an H-potential, and the control circuit (9, 9a, 9b, 9c) comprises a data terminal (5,5a, 5b, 5c) connected to the cathode of the light emitting diode (5,5a, 5b, 5c) A) for outputting an electrical data signal in data transmission mode. Data transmission and reception circuit according to any one of the preceding claims, characterized in that the control circuit (9, 9a, 9b, 9c) has a bidirectional port (17, 17a, 17b, 17c) for transmitting data with a terminal (9). A), through which in the data transmission mode transmits an electrical data signal, and through which in the data receiving mode 2846 the light-emitting diode (5, 5a, 5b, 5c). Data transmission and reception circuit according to any one of the preceding claims, characterized in that the control circuit (9, 9a, 9b, 9c) has a microprocessor for controlling the data transmission operation and the data reception operation, the data transmission and reception circuit. . Data transmission and reception circuit according to any one of the preceding claims, characterized in that the control circuit (9, 9a, 9b, 9c) has a serial interface for bidirectional asynchronous data transmission via a light-emitting diode (5,5a, 5b). 5c) in half-duplex operation. Data transmission and reception circuit according to any one of the preceding claims, characterized in that the light-emitting diode (5a, 5b, 5c) is arranged in a housing (25a, 25b) with a light-transmitting opening (21a, 21b) towards the light. a light-emitting diode provided with a button (23a, 23b) for manual data entry, wherein the data transmitting and receiving circuit is further switchable to data input mode by buttons under control of the idle control circuit (9a, 9b, 9c), the diode (5a) in push button data input mode is coupled at the anode side to the H-potential and at the cathode side to the high ohmic input (29) of the analog-digital converter (27) of the control circuit (9a) to record the diode voltage (5); the circuit (9a) comprises a microprocessor for evaluating the digital information transmitted from the analog-to-digital converter (27), for recording a sudden blackout of a housing bore (21a, 21b) changing the light passage to the diode as a manual data entry process. Data transmission and reception circuit according to one of claims 1 to 5, characterized in that the light-emitting diode (5b, 5c) is arranged in a housing with a light-transmitting opening (21b) towards the light-emitting diode provided with a button surface (23b) for manual data input, wherein the control circuit comprises a microprocessor circuit (9b, 9c) with a voltage control means for checking the idle voltage of the diode (5b, 5c), and wherein the microprocessor circuit (9b, 9c) is equipped to evaluate the light-emitting diode voltage information (5b, 5c), obtained from the voltage control means, to recognize the operation of the optical button by changing the brightness of the ambient light, the control circuit being equipped with a capacitor (31b, 31c) coupled to the light-emitting diode (5b, 5c) and a resistor ( 11b, 11c) connected to a connection point between the light-emitting diode (5b, 5c) and the capacitor (3b, 31c), the light-emitting diode (5b, 5c) being connected to the first m terminal (B) of the microprocessor circuit (9b, 9c) and on the cathode side via a resistor (11b, 11c) with a second terminal (C) of the microprocessor circuit (9b, 9c) as well as a capacitor (31, 31c) with H-potential the connector (D), wherein the microprocessor circuit (9b, 9c) is further provided with a high ohmic voltage-control lead (A) connected to a junction point between the light-emitting diode (5b, 5c) and the capacitor (31, 31c); is arranged such that the outlets (B, C) are controlled in two consecutive steps in such a way that in the first step the first outlet (B) leads the H-potential and the second outlet (C) is switched to a high ohmic three-position state, (31, 31c) is charged correspondingly to the no-load voltage of the diode (5, 5c), on the other hand, in a second step the first terminal (B) is switched to a high ohmic three-position state and the second terminal (C) leads L-potential so capacitor charge (3 1, 31c) and the supply voltage (A) decreases, the control circuit being equipped such that, as a measure of the no-load voltage of the light emitting diode (5b, 5c), it measures the time elapsing in the second step until the supply voltage (A) drops switching threshold voltage of supply (A). The data transmission and reception circuit according to any one of the preceding claims, characterized in that it is designed as an optical communication interface of a measuring device (52) adapted to optically exchange data with the second device (54). The data transmission and reception circuit according to claim 8, wherein the second apparatus as an optical communication interface comprises a data transmission and reception circuit according to any one of claims 1 to 7. Data transmission and reception circuit according to claim 8 or 9, characterized in that the first device (52) is an electronic consumption meter (50) which is installed at the point of consumption and the second device (54) is a portable reading device, directed to the first apparatus (52) to a data transmission position.