DE102004018923A1 - Electronic circuit of optical sensor, includes second component ensuring similarity with class of circuits at one point of characteristic curve - Google Patents

Abstract

The circuit has at least one second component (R1). This assures that the circuit at one point (UD1, UD2, UD3) of its characteristic curve (1, 2, 3) is so characterized that it is allocated to a class of similar circuits. The first component (D1) is a diode, especially a photodiode. The second component (R1) is an ohmic resistance. The relevant point (UD1, UD2, UD3) is the dark potential. The components (D1, R1 are connected in parallel. An independent claim is included for the corresponding method light sensor circuit classification.

Description

The The invention relates to an electronic circuit arrangement, in particular a light sensor with an individual characteristic curve, the through the individual characteristic curve of a first component of Circuit arrangement is conditional. Furthermore, the invention relates to a Method for classifying such an electronic circuit arrangement, an arrangement of a control unit and a light sensor and a method for adjusting such an arrangement.

Out the prior art are electronic circuitry, in particular light sensors of the type mentioned above. These have in dependence of the first device, which is mostly a photodiode, an individual characteristic curve. The further circuit, in such a circuit arrangement is used, for example a control unit, on which the light sensor is connected to must be adapted to the individual Be matched characteristic curve of the circuit arrangement. To are so far in the compilation of the circuit, respectively an arrangement of a control unit and a light sensor Justiervorgänge necessary. As soon as the electronic circuit arrangement, or the light sensor must be replaced after adjustment, such an adjustment must be repeated.

light sensors For example, in motor vehicles for the scheme, respectively Control of air conditioners needed. In case of failure of such a light sensor, the light sensor exchanged and the control unit the air conditioning to be adjusted to the new light sensor. For this is a special training of the workshop staff possible, what not always guaranteed can be.

Of the The invention is therefore based on the object, an electronic circuit arrangement, in particular a light sensor of the type mentioned above to modify, that the light sensors have a characteristic with which they can be assigned to a class, then a further circuit, in particular a control device accordingly to be able to adjust to the class. there It should also be possible in particular be that the controller automatic to the class of the light sensor.

These The object is achieved by a Electronic circuit arrangement according to claim 1, by a method for classifying an electronic circuit according to Claim 7, by an arrangement of a control device and a Light sensor according to claim 10 and by a method for adjusting an array from control unit and a light sensor according to claim 11.

Therefore has a circuit arrangement according to the invention in addition to the features mentioned above, a second component, that ensures that the circuitry over a point of their characteristic is characterized in that the circuit arrangement to a class of similar Circuit arrangements is assigned. In this second component it can be an ohmic resistance. On the other hand can the first component is a diode, in particular a photodiode, when it comes to the electronic circuitry to a Light sensor acts.

Based the point of the characteristic, is now the electronic circuitry in terms of class, the electronic circuitry is assigned, identifiable. As soon as you get that point on the Characteristic knows, one knows the class of the electronic circuit arrangement and can the rest Circuit in which the circuit arrangement is used, accordingly to adjust.

Of the Point of the characteristic of the circuit arrangement, for example be the dark voltage at a light sensor. The dark voltage is the point on the output voltage-luminous flux characteristic of the circuit arrangement, where the luminous flux is zero. In a circuit arrangement according to the invention can the first component and the second component otherwise parallel be arranged to each other.

A method for classifying an electronic circuit arrangement, in particular a light sensor, with an individual characteristic curve, which is caused by an individual characteristic curve of the first component of the circuit arrangement, can comprise the following steps:
In a step, the individual characteristic curve of the circuit arrangement without the second component used is determined under predetermined conditions. In a following step, the determined characteristic curve is evaluated in order then to assign the circuit arrangement to a class of similar circuit arrangements in a subsequent step. Then, in a further step, the circuit arrangement can be identified by means of the second component as belonging to the class, for which purpose the second component is inserted into the circuit arrangement or trimmed accordingly. In this second Component may be a trimmable component.

The first component may be a photodiode, wherein the individual Characteristic curve of the circuit arrangement at predetermined illumination conditions is determined.

The second component is advantageously an ohmic resistance, wherein by inserting and / or trimming this ohmic resistance the Dark voltage of the circuit can be set.

at an inventive arrangement a control unit and a light sensor of the aforementioned type, wherein the light sensor to the control unit connected to transmit the measured light to the controller, is the control unit first fixed to any class of sensors and can by means of a correction algorithm to the class of the connected sensor be connected.

To may be a method according to the invention for adjusting the arrangement, in particular for automatic adjustment of the control unit be performed on the individual characteristic of the light sensor. This inventive method includes that the correction algorithm after connection of the light sensor to the control unit the first measured value supplied by the light sensor as the value of the dark voltage of the sensor, which may be different from the actual one Dark voltage distinguishes that the correction algorithm is due of the first measured value, the light sensor of a class of light sensors assigns and the correction of the other measured values supplied by the light sensor according to the class makes, each time the light sensor provides a second reading closer to the actual one Darkness is the correction algorithm due to the second Measure the light sensor as to another class of light sensors belonging detects and corrects the other supplied by the light sensor Measured values according to the current assignment of the light sensor to make a class.

to execution of the correction algorithm, the control unit advantageously has a memory on, in the for each class of light sensors stored corresponding correction values are.

The The invention will be explained in more detail with reference to the drawing. It shows

1 Characteristic curves of three different light sensors according to the prior art,

2 Characteristic curves of three light sensors according to the invention and

3 a light sensor according to the invention.

One Light sensor according to the state The art has a photodiode as a photosensitive component on. Mass produced photodiodes are characterized by this from that the properties of the photodiodes in a wide range are scattered. Although the photodiodes usually have the same dark voltage, d. H. they deliver an equal voltage value in absolute darkness (about 0 volts), starting from this voltage, take the output voltages the photodiodes from photodiode to photodiode different values at the same luminous flux. This results in different ones Characteristic curves for the Photodiodes.

One Sensor as known in the art and a photodiode of the previously described type with individual characteristic, therefore, has due the individual characteristic of the photodiode also an individual Characteristic by which the sensor is different from other sensors Design differentiates.

photodiodes and sensors that are similar Properties, d. H. similar Characteristic curves have, can be assigned to so-called classes. Photodiodes, or light sensors of a class can be exchanged more or less against each other without significantly changing the characteristics of the circuit, in which uses the photodiode, or the light sensor is.

In the 1 the characteristic curves of different light sensors are shown. All three characteristics start at a common point in the dark and provide a dark voltage U _D in the dark, which is the same for all light sensors. For very large luminous fluxes, photodiodes also provide the same voltage values, which means that the light sensors according to the prior art provide a voltage value U ₀ for very large luminous fluxes, which is also the same for all three light sensors. Between the dark voltage and the voltage U ₀ run the characteristics 1 . 2 . 3 However, the three light sensors different. The characteristics differ essentially by their steepness.

The invention is based on the idea to classify the different light sensors, which means that the three light sensors with their characteristics 1 . 2 . 3 out 1 three different classes be assigned. To mark the affiliation of a light sensor to one of the classes, the light sensors are modified so that the classes can be detected on the basis of the dark voltage U _D1 , U _D2 , U _D3 . The dark voltage U _D1 , U _D2 , U _D3 is thus brought to a value for the light sensors of one class, which differs from the dark voltages of the other classes. For this purpose, a further component is used in the light sensors according to the invention, namely an ohmic resistor R ₁ . This ohmic resistor R ₁ contributes to the displacement of the dark voltage U _D1 , U _D2 , U _D3 concern. On the basis of the dark voltage or the value of the resistor R _{1 used} can thus detect the class to which the light sensor is assigned. It can also be interpolated between stored characteristics. In the light sensor according to the invention according to 3 the ohmic resistor R _{1 is arranged} parallel to the photodiode D ₁ . This parallel connection is via another circuit 4 , which is not shown in detail, is connected to the output of the light sensor, at which the sensor voltage U _S can be tapped. The light sensor can be connected to a control unit via this output.

Claims (11)

Electronic circuit arrangement, in particular light sensor, with an individual characteristic curve ( 1 . 2 . 3 ), which is due to an individual characteristic curve of a first component (D ₁ ) of the circuit arrangement, characterized in that the circuit arrangement has at least one second component (R ₁ ), which ensures that the circuit arrangement via a point (U _D1 , U _D2 , U _D3 ) of their characteristic ( 1 . 2 . 3 ) is labeled so that the circuit arrangement is assigned to a class of similar circuit arrangements. Circuit arrangement according to claim 1, characterized in that the first component (D ₁ ) is a diode. Circuit arrangement according to claim 1 or 2, characterized in that the first component (D ₁ ) is a photodiode. Circuit arrangement according to claim 1, 2 or 3, characterized in that the second component (R ₁ ) is an ohmic resistance. Circuit arrangement according to Claim 3 or 4, characterized in that the point (U _D1 , U _D2 , U _D3 ) of the characteristic curve ( 1 . 2 . 3 ) of the circuit, which is dark voltage. Circuit arrangement according to one of claims 1 to 5, characterized in that the first component (D ₁ ) and the second component (R ₁ ) are arranged parallel to each other. Method for classifying an electronic circuit arrangement, in particular a light sensor, with an individual characteristic curve ( 1 . 2 . 3 ), which is due to an individual characteristic curve of a first component (D ₁ ) of the circuit arrangement, characterized by, - a step in which under given conditions of the individual characteristic curve ( 1 . 2 . 3 ) of the circuit arrangement without at least one second component (R ₁ ) or with a trimmable second component is determined in a basic setting, - a subsequent step in which the determined characteristic curve is evaluated, - a subsequent step in which the circuit arrangement of a class is assigned by similar circuits, - a subsequent step, in which the circuit arrangement by means of the second component (R ₁ ), which is inserted into the circuit arrangement, and / or by trimming the second component as belonging to the class. A method according to claim 7, characterized in that the first component (D ₁ ) is a photodiode and that the individual characteristic curve ( 1 . 2 . 3 ) of the circuit arrangement is determined at predetermined illumination conditions. A method according to claim 8, characterized in that the second component (R ₁ ) is an ohmic resistance and that by inserting or trimming the second component, the dark voltage (U _D1 , U _D2 , U _D3 ) of the circuit arrangement is determined. Arrangement of a control unit and a light sensor according to one of the claims 5 or 6, wherein the light sensor is connected to the controller to the to transmit measured light to the control unit, characterized in that control device to a class of light sensors is fixed and by means of a correction algorithm to the connected light sensor is customizable. Method for adjusting an arrangement according to claim 10, in particular for the automatic adaptation of the control device to the individual characteristic of the light sensor, characterized in that the correction algorithm takes after the connection of the light sensor to the control unit, the first value supplied by the light sensor as a value of the dark voltage of the light sensor However, which differs from the actual dark voltage that the correction algorithm due to the first measurement, the light sensor of a Class of light sensors and corrects the other readings provided by the light sensor according to the class wherein each time the light sensor provides a second reading closer to the actual dark voltage, the correction algorithm based on the second reading is the light sensor of a different class from light sensors and corrects the other measured values provided by the light sensor according to the current assignment of the light sensor to a class.