WO2015025009A1 - Method for calibrating an apparatus for measuring an optical signal transmission path - Google Patents

Abstract

The method is used to calibrate an apparatus for measuring an optical signal transmission path, in particular for detecting an object and/or for detecting a movement and/or a direction of movement of an object. In this case, the apparatus is provided with at least one measurement transmitter (H1,H2,H3) for transmitting an optical measurement signal, at least one compensation transmitter (K) for transmitting a compensation signal in phase opposition with the optical signal from the at least one measurement transmitter (H1,H2,H3), and at least one receiver (D) for alternately receiving the optical signal from the at least one measurement transmitter (H1,H2,H3) and the optical compensation signal from the at least one compensation transmitter (K). During the method, when the measurement transmitter (H1,H2,H3) is deactivated, the at least one compensation transmitter (K) transmits a compensation signal, while the at least one receiver (D) receives this compensation signal. The amplitude of the compensation signal is set in such a manner that an electrical measurement signal having an amplitude above the amplitude of signal noise produced by the at least one receiver (D) and/or a drive- and evaluation unit (17) is established. Furthermore, an offset signal which is in phase opposition with the compensation signal and is therefore in phase with the measurement transmission signal and has an amplitude equal to the amplitude of the signal caused by the compensation signal from the compensation transmitter (K) in the signal path downstream of the at least one receiver (D) is provided.

Description

 Method for calibrating a device for measuring an optical signal transmission path

The invention relates to a method for calibrating a device for measuring an optical signal transmission path, in particular for detecting an object and / or for detecting a movement and / or a direction of movement of an object.

In this case, a photodiode is typically operated in the reverse direction. It has proved to be particularly advantageous to energize the photodiode for compensation of a (for example ambient) interference radiation resulting photocurrent by a voltage-controlled current source and to keep in a voltage-predetermined operating point.

In devices for optical signal transmission, such as are known, for example, under the name ^® HALIOS, there is a problem that the optical coupling of the optical property to each other in operative connection elements in a relatively high degree manufacturing and assembly is dependent. Therefore, it is expedient if such devices for measuring an optical signal transmission path are in particular automatically calibrated, not only during or after the manufacture of the device, but also during operation of the device.

Examples of apparatus of the aforementioned kind are described in EP-A-1 426 783 and WO-A-01/54276.

The object of the invention is therefore to provide a method for calibrating a device for measuring an optical signal transmission path, in particular for detecting an object and / or for detecting a movement of a signal. tion and / or a direction of movement of an object, with which the field of application of the device can be improved and expanded.

To achieve this object, the invention proposes a method for calibrating a device for measuring an optical signal transmission path, in particular for detecting an object and / or for detecting a movement and / or a direction of movement of an object,

 wherein the device is provided with

 at least one measuring transmitter for transmitting an optical measuring signal,

 at least one compensation transmitter for transmitting a compensation signal which is in phase opposition to the optical signal of the at least one measuring transmitter,

 - At least one receiver for alternately receiving the optical signal of the at least one measuring transmitter and the optical compensation signal of the at least one compensation transmitter and

 a control and evaluation unit for controlling the at least one measuring transmitter with a first modulated drive signal, the at least one compensation transmitter with a second modulated drive signal and the at least one receiver for transmitting the optical measurement signal or the optical compensation signal or for the purpose of receiving an optical signal and the Evaluation of the received optical signal for generating an evaluation signal representing the measurement of the optical signal transmission path, and

 wherein in the method

When the measuring transmitter is deactivated and thus not controlled by the modulated control signal, the following calibration steps are carried out: the at least one compensation transmitter transmits a compensation signal and the at least one receiver receives this compensation signal, and

 the amplitude of the compensation signal is set in such a way that an electrical measurement signal with an amplitude which is above the amplitude of a signal noise generated by the at least one receiver and / or the control and evaluation unit is set in the control and evaluation unit Performing these calibration steps is calibrated and during a subsequent, taking place for the purpose of detecting an object and / or movement of an object and / or a direction of movement of an object transmitting modulated Messsendesignalen from the control and evaluation for controlling the compensation transmitter in anti-phase to the compensation signal and in order to provide modulated offset signal in phase with the measuring transmission signal for the at least one measuring transmitter having an amplitude which is equal to the amplitude of the in the signal path behind the at least one receiver by the compensation signal of the comp ensationssenders signal is.

In the apparatus for measuring an optical signal transmission path to be calibrated according to the invention, both the at least one measuring transmitter and the at least one compensation transmitter with modulated signals are used, these signals being out of phase, ie 180 ° out of phase. The device is then in its regulated state when the at least one receiver receives a DC signal, the amplitudes of the optical signals from the transmitter and the compensation transmitter are thus the same. This regulated system is "disturbed" at the moment in that there is a previously non-existent object in the optical signal transmission path between the at least one measuring transmitter and the at least one receiver. This object reflects Ieh shares of the optical Meßsig signal into the at least one receiver into it. The further away the object is from the at least one measuring transmitter or at least one receiver, the weaker is the reflected signal which the receiver still receives. By means of, for example, a differential image of the received compensation signal and of the received measurement signal reflected on the object, an evaluation value representative of the distance of the object can then be determined. As already mentioned above, this type of measurement of optical signal transmission paths is known under the name HALIOS and described, for example, in DE-A-102 56 429.

According to the invention, such a device can be compensated for by ensuring that an evaluation is possible, even with the smallest amplitudes of the measured signal reflected by an object and received by the receiver. The smallest signals to be processed of the device for measuring the optical signal transmission path are primarily determined by the system noise, which in turn is determined primarily by the noise behavior of the receiver and / or the control and evaluation unit. The problem is that the system noise can vary from device to device because even with one and the same application, the optical coupling may vary from device to device. Thus, the system noise of each device must be measurable to calibrate the device.

According to the invention, in the apparatus for measuring an optical signal transmission path, the at least one compensation transmitter is used by operating this transmitter with the transmitter or transmitter deactivated, until an electrical signal occurs in the control and evaluation unit which is above the system noise is located and thus "detectable" is. The amplitude of the Kompensationssig nals, to a (just) still "detectable" electrical signal innenhal b the control and evaluation, d. H . leads to a measured signal above the system noise, nu is used to synchronize with this amplitude optical measuring signal liestel lying electrical offset signal which during the later use of the device for the purpose of measuring an optical signal transmission path is superimposed on the optical Messsig signal. Thus, even the smallest portions of the measuring signal received by the receiver are present above the system noise and can thus be used in the control and evaluation unit to form an evaluation signal representing the distance of an object from the apparatus. In addition, each device calibrated in this way behaves the same way (of course under tension of the same application type).

It should again be emphasized at this point that, during the calibration, the at least one measuring transmitter or each measuring transmitter is completely deactivated, ie it is not loaded with modulated control signals. During the calibration phase, therefore, only the compensation transmitter is operated, with a modulated signal.

It is expedient to increase the amplitude of the compensation signal from low values, in particular also from zero to larger values h in, in order to determine from when the electrical measuring signal settling in the control and evaluation unit has an amplitude has above the system noise. An approximation to this operating point "from above" is fundamentally also possible, but assumes that the amplitude of the compensation signal leads at least once to an electrical measurement signal with an amplitude that is less than the system noise, in order to start d iesem point the amplitude of the Kompensationssig signal then increase again until the electrical measurement ^¬ signal of the control and evaluation has an amplitude slightly oberhal b of the system noise.

The invention will be explained in more detail below with reference to an exemplary embodiment and with reference to the drawing. In detail, they show:

Fig. 1 an overview of the overall system as a block circuit diagram, Fig. FIG. 2 shows the time characteristic of different signals of the overall system according to FIG. 1 during a measuring interval or during a measuring cycle us and FIG. 3 and 4

 Diag ramme to clarify a (auto) calibration of the entire system.

The inventions will be described below with reference to a device for störstrahl ungs compensated control of a photodiode and the evaluation of the photocurrent, the al lerdings contains features that are not essential for Realization of the invention.

In the Störstrahl ungskompensierten device, the receiving diode D is operated via two connections. Via the circuit nodes 61, 62, the receiving diode D is energized by two controlled current sources 27, 28. In this case, two amplifiers 26, 29 detect the potentials on the input lines 30, 31 outgoing from the terminals. If, for example, the operating point of the diode changes as a result of permanent irradiation with sunlight, the generated photocurrent changes. The Spannungsabfal l on the receiving diode D changes and the working potential of the input lines 30,31 and thus at the inputs of the amplifier 26,29. This is registered by the amplifiers 26,29. These compare the potentials on the input lines 30,31 each with a reference potential Refl, Ref2. The outputs of the amplifiers 26, 29 now regulate the current circuits 27, 28 in such a way that the voltage values of the input lines 30, 31 again correspond to the specifications. Coupling capacitors 24, 25 form a barrier to the DC voltage levels on the input lines 30, 31 to downstream circuits. The capacitors 24, 25 are connected on the side facing away from the terminals to the inputs to measuring amplifiers 18, 19. The outputs 33, 34 of the measuring amplifiers 18, 19 are each fed back via adjustable capacitances 20 and 21 to their inputs. A differential stage 35 forms the differential signal nal 63 of the two amplifier output signals. Ideally, this signal 63 should represent the useful signal of the photodiode.

As described above, the control outlined above by the amplifiers 26,29 of the two voltage-controlled current sources 27 and 28 and the change in the setting of the current sources 27,28 leads to a load on the useful signal, which limits the range massively.

The device according to the invention or the inventive method is now based on the recognition that in most applications, in particular ^¬ sondere associated with a gesture control for mobile devices, a permanent measuring operation is not necessary or desirable. Such an operation consumes energy that is extremely "precious" especially for mobile devices, because it is limited in availability.

The device should therefore be operated time-dependent in different system states, ie in individual time-separated and consecutive measurement intervals, each having at least one measurement phase. In the ^¬ sem measuring state readjustment off virtually by the current sources 27,28. Only the capacitors 24,25 hold the respective operating points. This is equivalent to a change in the internal resistance of the current sources 27, 28.

However, such a poor (because "sluggish") control prevents the adaptation to an external light irradiation. It therefore makes sense to define a further state per measurement interval, namely a (measurement) preparation phase in which the internal resistance of the current sources 27, 28 is minimal. In this state, the power sources quickly regulate. A useful signal would be heavily loaded and distorted in the preparation phase. Therefore, no measurement is carried out in this preparatory phase. In a sample-and-hold circuit, not shown, the result of the respective measurement is typically buffered.

However, a problem that now arises is that a disturbance that occurs during a measurement may over- or underdrive the sense amplifiers 18, 19.

Such a disturbed measurement result is not usable. Therefore, it makes sense to quantitatively evaluate the measurement result.

In the simplest case, this can be done, for example, by the measuring amplifiers 18, 19 each outputting one signal for overdrive and one signal for understeer. Thus, 16 states of the system of two amplifiers 18,19 are possible with two evaluation signals. Of these, not all make sense because, for example, a simultaneously occurring over- and understeer is not realistic, but still faulty.

Nevertheless, the four-bit word formed in this way forms a quantitative assessment of each measurement result.

In contrast to the prior art, therefore, no transimpedance amplifiers, but integrators, which are part of said measuring amplifiers 18, 19, are used at the input of the system. The sequence of a measuring interval is controlled, for example, by the digital control block 4 of the (block) circuit diagram according to FIG. Through the sequence control, a measurement activation signal "Measure" (reference number 66, FIG. 2) is activated at the beginning of the measurement (reference number 67, FIG. 2). This starts the first preparation phase A. In this phase A, the current sources 27, 28 regulate the operating point of the receiving diode D at low impedance. The output of the power supply for a compensation diode K is switched active ^¬ . As a result, the compensation diode K already irradiates the photodiode D. Die Compensating diode K is initially not modulated. Due to the low resistance of the current sources 27, 28, the measuring amplifiers 18, 19 quickly reach their operating points. The capacitors 20,21 and coupling capacitors 24,25 are charged to their working levels. The current sources 64, 65, 66, 67 for the operation of three measuring transmitting diodes H1, 1-12, 1-13 (because of the multidimensional, in particular 3D gesture recognition) and the compensation diode K in this embodiment are set to the respective operating values.

At the end of phase A at time 69 (FIG. 2), the signal "hold" (see reference numeral 68, FIG. 2) becomes active. The voltage-controlled current sources 27, 28 go from their hitherto assumed low-impedance state into a high-resistance state. This "frozen" their work points. At this point in time, the difference signal 63 of the outputs of the measuring amplifiers 18, 19 should be constantly zero, since the operating points are adjusted.

Since switching to the high-impedance state also leads to faults, it makes sense to let some time pass until the actual measurement begins. This time is called stabilization phase or second preparation phase B (Figure 2). It ends at time 70 (FIG. 2).

In the simplest case, the modulation signals 45, 46, 47, 48 for the compensating diode K or for the measuring transmitting diodes H1, 1-12, 1-13 are square-wave signals which are phase-shifted by 180 ° and whose amplitude can be regulated (see Measuring phase C Fig. 2).

The measurement begins by z. B. the radiation of the compensating diode is attenuated or even switched off (see reference numerals 45 and 69 in Figures 1 and 2). At the same time is typically at least one of the transmission signals ^¬ (1 and 2 refer to reference numeral 46 and / or 46 and / or 47 in Figs.) Is ON. The typically at least one Meßsendediode Hl and / or H2 and / or H3 irradiated with detour over the to be measured Transmission path, the (receiving) photodiode D. For several transmitting diodes they are controlled sequentially (eg cyclically).

The compensation transmitting diode K and the typically at least one measuring transmitter diode Hl or H2 or H3 are alternately attenuated or caused to increased radiation. First, this will result in a residual modulation of the output of the input stage. After amplification by an amplifier 36, the thus-received modulated signal can be converted into a DC signal by a demodulator. This can be used to control the amplitude of the modulation of the one Meßsendediode or each one of the transmitting diode Hl, 1-12,1-13 and / or the amplitude of the modulation of the compensation diode K.

In FIG. 2, a control of the compensation diode K is shown by way of example as the case F1 and, as the case F2, a regulation of the measuring transmitter diode or diodes H1, H2, H3 is shown. The control can be different for the measuring transmitter diodes H1, H2 and H3. Typically, moreover, the measurement transmit ^¬ the H1, H2 and H3 are not operated simultaneously but with a time delay. In this case, more than one receiving diode can be used. The time offset is then typically selected so that only one reception ^¬ diode D and a transmitter diode H1, H2, H3 are simultaneously active.

In the following, the regulation on the change of the modulation amplitude of the transmitting diode H1, H2, H3 will be explained.

Here, the measured value thus obtained by H3 regulates the amplitude of the respective measuring ^¬ transmitting diode H1, H2,. It has been shown that it makes sense to increase this value before the negative feedback. This principle is also known from operational amplifier circuits and serves to suppress parasitic factors and influences. For a better understanding, reference is hereby made to the following documents and patent applications, the contents of which, in combination with the technical teaching disclosed here, form part of this application DE-B-103 46 741, EP-A-2 546 620, EP-A-2 356 000, EP-B-1 410 507, EP-B-1435509, EP-A-2418512, EP-B- 1 269629, DE-A-10322552, DE-B-10 2004 025 345, EP-A-2 405 283, DE-C-44 11 773, WO-A-2012/163725, DE-A-2006 020 579, DE-B-10 2005 045 993, EP-B-1 979 764, DE-A-10 2012 024 778, DE-A-10 2013 000 376, DE10 2013 003 791.3, DEA-10 2013 000 380, WO-A -2014 / 096385, WO-A-2013/124018, DE-B-102013002304, EP-A-2624 019, DE-A-10 2012 025 564, DE 10 2013 002 674.1, DE-A-10 2013 222 936, DE-A-102012015442, DE-A-102012015423, DE-B-102012024597, EP-A-2679982, EP-A-2597482, DE-A-102013002676, EP-A-2653885.

The regulation ideally sets up an equilibrium and the output signal 50 of the demodulator 37 constitutes, after said amplification, a measure for the attenuation of the transmission signal in the transmission channel. The control according to the invention of the current sources 27, 28 starts at the input lines 30, 31 in FIG an input resistance to the effect remark ^¬ bar, that the current sources in dependence of typically at least two phases of a measurement cycle fluctuate (reference numeral a and C, B and C or a and B and C of FIG. 2).

Of course, the effectiveness of the voltage controlled current sources 27,28 is limited by the real conditions. The current sources 27, 28 can only try to keep the given voltage level up to a maximum current.

The measuring interval (from reference numeral 67, Fig. 2, to reference numeral 71, Fig. 2) is terminated by the fact that the "Measure" signal (66) at the end of Messzyk ^¬ lus (see reference numeral 71, Fig. 2) again inactive becomes. All transmit signals are turned off and the measurement result is typically frozen, for example, in a sample-and-hold circuit (not shown). Depending on the application, it is expedient to repeat such a measuring interval (from reference numeral 67, FIG. 2, to reference numeral 71, FIG. 2) at regular intervals in shorter or longer time intervals. Higher repetition rates for the measurement sequences, however, result in a higher current consumption.

As a further measure for improving the optical distance measurement, the system may be able to provide at least some and typically each measured value with a quality value of the measurement, ie to carry out a measurement signal quality determination. Within the scope of this application, this measure forms a subject matter of the invention.

Thus, at several successive measurement intervals, a sequence of measured values with associated quality values results, which allow a measured value estimator to estimate an optimized measured value and to indicate a probability of correctness of this measured value. The resulting measured value vector can be used, for example, as the basis for the feature extraction of a gesture recognition. This is particularly useful if a disturber, such. As sunlight, with relatively low frequency (for example, due to shading d urch eg trees), but such. B. with fluorescent tubes or when driving in a convertible in the sunshine under trees hind urch relatively fast l mod ul is. If the disturbance frequency is close to the modulation frequency of the measured transmit modes H l, 1-12,1-13 and the compensation transmitter K, this freq uence is generally not hit correctly. There is a beating in the regulatory signal that can be detected and used. The quality of the measurement will typically vary with time depending on the beat frequency. Since the system only evaluates such measured value sequences as a result of the evaluation of the measurement results, ie they are relatively undisturbed, it is thus in fact automatically necessary to sample the measurement signal only at relatively undisturbed times. In addition, it is conceivable that not only as disturbed detected measured values are discarded, but also those for which an estimator determines a high probability of failure. These can be, for example, directly preceding or directly following measured values. Also, such a measuring system should initiate countermeasures for detected disturbances.

This includes, for example, a change in the measurement frequency. This can be both the repetition frequency of measurement intervals and the Modulationsfre ^acid sequence of Measuring diodes St., 1-12,1-13 and the compensation transmitting diode K concern. Also, the circuit can be parameterized differently. For example, the time constants of the measuring amplifiers 18, 19 acting as integrators can be changed by changing the capacitances 20, 21. In extreme cases, the integrators can be bridged by bridging their capacitances 20, 21 with the aid of the programmable switches 22, 23. So, as you can see from this example, a change in the system or circuit topology comes into question. The integrators then become ^pure impedance transformers.

A further improvement of the device can thus be achieved by an assessment of the quality of the measurement signal and / or by a control for optimizing the measurement results. In general, the feedback loop is closed by ^¬ software since the control algorithms are highly application dependent. As an actuator for this measurement signal quality control typically serves a change in the system parameters and / or the system topology or structure.

Another possibility, which can be included in the quality evaluation of a measurement result, is the evaluation of the current source currents. For this purpose, in block 16 ("extrinsic light measurement" or "measurement of the external light"), the current measured by the current source or current sources 27, 28 is measured as a function of time. These measurement results can be made available to the software. be presented. This can determine, for example by a Fourier transformation, the interference frequencies that disturb the measurement signal. It is particularly advantageous to respectively select the modulation frequency of the measuring transmitting diodes H1, 1-12, 1-13 and the compensation diode K and the repetition frequency of the measuring intervals (reference number 67, FIG. 2, to reference number 71, FIG. 2). that they do not interfere with the interference frequencies as possible. Thus, for example, by "frequency hopping" the noise robustness can be increased. Furthermore, it is conceivable to use instead of a single-frequency transmission signal a band-limited signal and so narrowband interferers, for example, by a spread Spectra process in their influence on the measurement result to reduzie ^¬ ren. Such possible transmit signals suitable pseudorandom follow (see also EP-A-2 631 674, the content of which is hereby incorporated by reference)

A further an independent inventive concept representing measure is the introduction and / or increase a threshold for detecting the approach of an object to the measurement end of diode Hl, H2, H3 / receiving diode D. Here, If it is a non-linear Fil ^¬ terfunktion, typically in the Block 37 of FIG. 1 is realized, but can also be implemented in a subsequent processing stage. All measured values below or above a threshold are fixed to a predefined value, for example.

Finally, due to the measurements a mathematical model of a Stö ^¬ insurer can be parameterized and times and setting parameters for the measuring system are forecast at and with which the next measurement interval can be performed with a very good quality. Below is a further particularity of the circuit of FIG. 1 will be discussed, in which it is a further independent inventive idea. Especially for mobile applications, it is particularly important to use as little energy as possible. Therefore, it is particularly favorable, as above beschrie ^¬ ben who Measuring diodes or one of the Measuring diodes St. modulating 1-12,1-13 and not compensation diode K and operate the system only when needed. In order to reduce the required operating power on, it is advisable not to operate the system if it is for example completely shadowed from ^¬. This is the case when used in a mobile telephone, for example, when the user holds the telephone to his ear for telephoning. For the detection of such usage situations, it is therefore useful to provide another, typically passive sensor, which can pre-classify the usage situation, for example by measuring the ambient light. Here, too, the use of an internal resistance-modulated interference radiation compensation circuit may be useful if modulated signals are to be detected. The circuit according to FIG. 1 has such an interface 53 (see top right in FIG. 1), which is provided with a corresponding input hardware 7.

In addition, it may make sense to put the whole system into an ^energy-¬ saving mode to reduce energy consumption even further. It should be noted that modern integrated circuits typically operate internally at a lower voltage than their peripherals. In that regard, a voltage regulator 1 is advantageous, which provides the internal operating voltages. This voltage regulator 1 unnecessarily consumes energy in energy-saving mode. It is therefore useful to have a possible klei ^¬ nen part (see function block 14) to realize the circuit so that it can be operated directly with the operating voltage. This block 14 has only the task via an interface 54 to 57 the Minimalkom ^¬ munication to the main processor, with which the measuring system communicates, sure. The interface has, for example, a serial TX and RX two-wire line or an I ² C bus interface 54, an interrupt output 55 for the main processor, which must be at a defined potential, a non-maskable measuring system reset 56 and a reference voltage input 57. All other systems are switched off. If possible, the normal system oscillator 6 is also switched off and instead this function block 14 of the circuit is supplied with a low frequency from a minimum oscillator 5. This one is much smaller because it does not have to drive the entire IC.

Thus, in the power save mode, only the standard blocks 14 and 6 are active. Switched from ^¬ is particularly the band-gap reference 2, the block 4 (digital control), the voltage regulator 1 and all the measuring amplifier and receiving and transmitting devices.

If it is at the interface 54, for example an I ² C interface ^¬, so it makes sense to design the function block 14 so that it can detect a specific command on the bus only that sent to an exactly predetermined register address becomes.

Such a protocol can, for example, be such that the function block 14 recognizes a sequence from a start bit and the slave address and from a bit for signaling a write access and then issues an acknowledge bit, whereupon the main processor sends the register address, the function block 14 sends an acknowledge bit and the main processor then sends a parity bit. If the function block 14 has recognized all these data as correct, the voltage regulator, the bandgap reference 2 and all other parts of the circuit are started up in a predefined sequence one after the other and / or in parallel, depending on the type and requirement. The normal I ² C bus communication is then taken over by the block 4 (Digital Control) again until a next sleep command. Upon receipt of such a sleep command, block 4 (Digital Control) initiates the essential Parts of the measuring system to go into energy-saving mode. However, the last part of the shutdown sequence must be controlled by function block 14. This particularly relates to the shutdown of the power supply by switching off the voltage regulator 1, the oscillator 6 and the block 4 (Digital Control) itself.

It also makes sense if the function block 14 has an internal timer which can wake up the system at regular intervals, without requiring the reception of a command of the main processor via the interface 54.

It may be expedient if the system changes back into the energy-saving mode after carrying out measurement intervals predefined in terms of number and type, without requiring a separate command from the main processor via the interface 54 from the outside.

This is useful if the measured values and preferably also the measured value ^¬ qualities are stored in a (not shown) memory. The measured values stored there can also include configuration data of the system (for example with which of the transmitting diodes H1, H2, H3, with which the compensating diode K and with which receiving diode D and with what quality measured values were recorded.) The measurement results of further measuring signal evaluation blocks such as For example, the block 16 (Extrinsic Light Measurement) are stored.

In normal measuring mode, however, no energy may be "wasted" despite the energy-saving mode. Therefore, for example, the bandgap reference 2, which only supplies a reference voltage for use at various points in the measuring system, can be switched off temporarily if their voltage is buffered and buffered in a sample-and-hold circuit, for example. The bandgap circuit is then only for renewing the inevitably slowly draining charges from the memory element of Sample-and-hold circuit (typically a capacitor) turned on from time to time.

The feature essential to the present invention results from the necessary calibration of the measuring system.

Hierzu is in Fig. FIG. 3 shows the control characteristic of the system when the transmitter diode amplitude Tj is controlled. The Ampl itude of the jeweil strength Messsen ^¬ dediode H 1, H 2, H3 attributable fraction (see 72,75,77 in Fig. 3) of the photoelectric current I _PD in the / a receiving diode D depends on the sended io ^¬ denamplitude Tj off. The amplitude of the iode to the compensating diode K and depending ^¬ stays awhile Kompensationsd K attributable fraction (see Lin ie 73 in Fig. 3) of the photoelectric current I _PD in the / a receiving diode D will depend on the contrary, from the transmitter amplitude T, not decrease.

When the regulator is settled, the difference signal 63 is a DC signal. The attributable to the transmitted signal portion is then in Differenzsig ^¬ nal 63 zero. The maximum distance at which an approaching the Empfangsd iode ^¬ of the object or up to which a iode of the Empfangsd leaving object can still be recognized is determined d urch the control characteristic and / or fact that, in maximum amplitude of the transmitted iodine signal from the object is reflected so g roßer proportion of Sendediodensignals that iode at the Empfangsd a signal with at least the amplitude of the Kom ^¬ pensationsd iodensignals is received. For a g Rossen photocurrent 72 g is facilitated synonymous with a nearby object (and thus a steep rule ^¬ characteristic) to 74 gives it as the intersection point 73, a first operating point for a nied complicated photocurrent 75 (and thus at shallower control characteristic ) another second operating point 76. For very distant objects, however, the reflected light can become so low that no working point can be produced at all. The control characteristic in Fal le of the photo stream 77 is then so flat that no more intersection with the Line 73, which represents the amplitude of the compensation diode K, so that no meaningful control is possible.

Here, there are two possibilities: Either the compensation diode signal is controlled down at such weak receiver signals, which corresponds to a mixed control and has a higher circuit complexity, but can be realized quite successfully, or to the receiver signal is synchronous to the transmission signal offset signal added, which the working points 74,76 all by rotation-stretching around the point PO moves (see 74 ', 76' in Fig. 4) and a new operating point 78 for the new photocurrent 77 'is created. The offset signal leads to an inaccessible region 79 in the diagram of FIG. 4. The generation of this offset signal is indicated in FIG. 1 by a calibration block 81, which for the respective transmitter / receiver combination comprises the transmitter signals 9 to 12 generates the offset signal 82, from which the signal is evidence 82 by summing he ^¬.

For the calibration of an overall system that are part of the herein described Sys ^¬ tem and a further independent inventive idea det education, is now measured this entire system in a defined measurement setup. The overall system differs from the measuring system in that, in addition to the measuring system, it also includes optical elements such as mirrors, diaphragms etc. and, of course, the housing. For calibration, the compensation diode K is switched to a static level. The coupling between the receiving diode D and the compensation diode K is very difficult to stabilize according to experience. Therefore, the coupling is always the same as an application type, but it is assumed to fluctuate from application to application within the same type.

The calibration is now carried out so that the switchable reference current sources 41,42,43 are provided, with which the reference power supply 38 now is adjusted so that the measured photocurrent is always set to a same, application-specific default value. As a result, the ordinate position of the line 73 in Figs. 3 and 4 are given. This ensures that an operating point is found. This working point is typically set in such a way that the compensating transmitting diode current is increased until the compensation signal above the system noise becomes measurable. Subsequently, the offset signal is set to such a value that the lowest operating point is assumed.

The essential features of the aforementioned subject ^matters can be summarized in subgroups as follows:

Fremdlichtrobuste device for measuring at least one optical transmission path, characterized in that they

 has at least one recipient (D) and

 has at least one transmitter (Hl, H2, H3) and

 at least said receiver is connected to at least one gyrator or other interfering radiation compensation unit, and

 at least said gyrator at different times has a different internal resistance.

Device according to figure 1, characterized in that the receiver is a photodiode or other optical receiver which provides a photocurrent as a signal.

3. Device according to one or more of the preceding figures, characterized in that the measurement is not continuous but in measuring cycles. 4. Device according to item 3, dad urch in that at the beginning of at least one measuring cycle us a first preparation phase or the like preparation phase for stabilizing the operating point of the receiver ^¬ gers d passes.

5. Device according to item 4, characterized in that during a first preparation phase (A) the at least one gyrator is lower resistance than at a time outside of the preparation phase (A). 6. Apparatus according to item 4 or 5, dad urch in that

 it has at least one compensation transmitter (K) and transmits during a first preparation phase (A) the at least one compensation transmitter (K).

Device according to one of the numbers 3 to 6, dadu rch characterized in that during the at least one measurement cycle, following the first preparation phase (A), a second preparation phase (B) for Stabili ^¬ tion of a regulator d is passed.

Device according to item 7, characterized in that during the second preparation phase (B) the at least one gyrator is higher-impedance than at other times, in particular a time outside the second preparation phase (B). 9. Device according to item 7 or 8, characterized in that

 it has at least one compensation transmitter (K) and during the second preparation phase (B) the at least one compensation transmitter (K) is transmitted and modulated.

A device according to any one of items 3 to 9, dad urch geken nzeichnet that during at least one measurement cycle in Ansch ents to the second pre ^¬ preparation phase (B), a measuring phase (C) is traversed. Device according to item 10, characterized in that during the measuring phase (C) the at least one gyrator is higher-impedance than at a time outside the measuring phase (C) and the second preparation phase (B) of the measuring interval.

Device according to item 10 or 11, characterized in that

 it has at least one compensation transmitter (K) and in at least one measurement phase (C) at least one compensation transmitter (K) is transmitted and modulated.

Device according to one of the numbers 10 to 12, characterized in that in at least one measuring phase (C) at least one transmitter (Hl, H2, H3) is transmitted and modulated.

Device according to one or more of the preceding figures, characterized in that

 it has at least one compensation transmitter (K) and at least temporarily at least one transmitter (H l, 1-12,1-13) and the said compensation transmitter (K) are transmitted and modulated.

Device according to item 14, characterized in that for modulation the at least one compensation transmitter (K) and the at least one transmitter (H) takes place in such a way that at least portions of the compensation transmission signal of said compensation transmitter (K) at least temporarily complementary to the transmission signal of said transmitter (H1, H2, H3) are.

Device according to item 14 and / or l5, characterized in that the radiation of at least the said compensation transmitter (K) and at least of said transmitter (H1, H2, H3) are superposed in the receiver (D) in an additive or multiplying manner. Device according to item 0, characterized in that at least during a period in which at least one transmitter (Hl, H2, H3) and said compensation transmitter (K) are transmitted and modulated, at least said compensation transmitter (K) and / or said Transmitter (H) are controlled in the amplitude and / or phase so that the receiver (D) receives no more shares at least a predetermined part of the transmission signal or substantially only during a predetermined measurement phase (C) to system noise and Einregelfehler a DC signal receives. Device according to one or more of the preceding figures, characterized in that an offset signal (82) can be added to the receiver signal which is at least in portions at times in phase synchronism with the at least one transmission signal (9, 10, 11) of at least one transmitter (H l , 1-12,1-13) and corresponds with it.

B EZUGSZE IC H E N LIST Voltage regulator

Bandgap reference

function block

Digital control block

minimal oscillator

system oscillator

Input Hardware

signal line

signal line

signal line

signal line

function block

function block

Drive / evaluation unit

measuring amplifiers

measuring amplifiers

capacities

capacities

switch

switch

coupling capacitors

coupling capacitors

amplifier

power source

power source

amplifier

input line

input line

output

output

differential stage amplifier

demodulator

Reference Power

Reference current source

Reference current source

Reference current source

modulation signal

modulation signal

modulation signal

modulation signal

output

interface

RX two-wire cable of the interface

Interrupt output of the interface

Measuring system reset of the interface

Reference voltage input of the interface

circuit node

circuit node

difference signal

power source

power source

power source

power source

time

time

photocurrent

Amplitude of the compensation diode representing line operating point

photocurrent

working

photocurrent

photocurrent 78 operating point

 79 area

 81 Calibration block

 82 offset signal

Hl measuring transmitter diode

H2 measuring transmitter diode

H3 transmitter diode

PO point

 Refl reference potential

 Ref2 reference potential

A first preparation phase of the measurement interval

B second preparation phase of the measurement interval

C Measurement phase of the measurement interval

 D receiving diode

 K compensation diode

Claims

claims

1. A method for calibrating a device for measuring an optical signal transmission path, in particular for detecting an object and / or for detecting a movement and / or a direction of movement of an object,

 wherein the device is provided with

 at least one measuring transmitter (Hl, 1-12, 1-13) for transmitting an optical measuring signal,

 at least one compensating transmitter (K) for transmitting an optical signal of the at least one measuring transmitter (Hl, 1-12, 1-13) in antiphase compensation signal,

 at least one receiver (D) for alternately receiving the optical signal of the at least one measuring transmitter (H1, H2, H3) and the optical compensation signal of the at least one compensation transmitter (K) and

 a control and evaluation unit (17) for controlling the at least one measuring transmitter (H1, H2, H3) with a first modulated drive signal, the at least one compensation transmitter (K) with a second modulated drive signal and the at least one receiver (D) for transmitting the optical measurement signal or the optical compensation signal or for the purpose of receiving an optical signal and for evaluating the received optical signal for generating an evaluation signal representing the measurement of the optical signal transmission path, and

 wherein in the method

If the measuring transmitter (H1, H2, H3) is deactivated and thus not controlled by the modulated control signal, the following calibration steps are carried out: - The at least one compensation transmitter (K) sends a compensation signal and the at least one receiver (D) receives this compensation signal, and

 the amplitude of the compensation signal is set in such a way that an electrical measurement signal with an amplitude which is above the amplitude of one of the at least one receiver D and / or the control and evaluation unit (17) is set in the control and evaluation unit (17). 17) generated signal noise,

wherein the device is calibrated after carrying out these calibration steps and during a subsequent transmission of modulated measuring transmission signals from the control and evaluation unit (17) taking place for the purpose of detecting an object and / or a movement of an object and / or a movement direction of an object for controlling the compensation transmitter (K) provides an opposite phase to the compensation signal and thus in phase with the measurement transmission signal modulated offset signal having an amplitude equal to the amplitude of the in the signal path to the at least one receiver (D) by the compensation signal of the compensation transmitter (K ) is evoked signal.