DE29924916U1 - Optoelectronic device for detecting objects in monitored region - Google Patents

Abstract

The device uses a light transmitter (2) and a light receiver (5) having a near-field element and a far-field element. The receiver (5) has several segments, some used for the near-field element, and the rest for the far-field element. The segments may be formed by photodiodes, provided with individual amplifiers.

Description

The The invention relates to an optoelectronic device according to the preamble of claim 1.

A Such device is the light sensor of the series 46 of the Leuze electronic. Such devices typically become for object detection during monitoring used by machinery or equipment. Through a suitable evaluation the received signals at the outputs the near and far elements eliminate unwanted background effects, which distort the object detection would. The light spot of the received light beams is applied to the receiving element so focused that one Proportion of light on the Nahelement and a share on the Fernelement falls. exceeds the difference of the received signals a switching threshold, so is a Object message generated. The received signal corresponds to the height of Switching threshold, if an object corresponds to one of the scanning distance Distance to the device is located. Once the object is at shorter distances to the device is the difference of the received signals above the switching threshold, which corresponds to object detection. Light reflected from the background falls predominantly on the remote element and leads therefore not to an object message.

Of the Disadvantage of this device is that for detection in Close range one opposite the far element requires much larger area of the adjacent elements, what different sized capacity values the trained as photodiodes Nah- and remote elements result Has. The big capacity values of the near element limit the signal rise times and by the Capacity differences arise unwanted Signal overshoots in the difference.

One Another disadvantage is that for adjusting the scanning distance a mechanical displacement device is required, wherein the Movement path is non-linear to the scanning distance to be set. at larger scanning distances becomes a high setting accuracy and with small detection ranges greater Displacement required.

Other Devices use a CCD line as a receiving element. The disadvantages In this case, all individual signals are read out and processed serially Need to become and thereby processing times of more than 100μs arise. In addition, the Line width is much smaller than 1 mm, which makes only part of the Receiving light can be detected.

Of the Invention is the object of a device of the initially so-called type so that the simplest possible and accurate flexible range adjustment is possible.

to solution This object, the features of claim 1 are provided. advantageous embodiments and appropriate training The invention are described in the subclaims.

According to the invention the optoelectronic device is divided into several segments Receiving element, wherein a predetermined number of these segments to the Nahelement and a predetermined number of remaining segments to the remote element linkable are.

By an adaptation of the lengths the individual segments to the distance-dependent displacement of the light spot The reception light beams may be the electronic scanning range switching be largely linearized.

By the evaluation of multiple receive segments can the validity of the switching signal on plausibility checked and disorders be recognized.

In a particularly advantageous embodiment, the individual Segments each formed substantially the same area. there each segment is followed by a separate amplifier, wherein the Output signals of the ampli ker be evaluated in an evaluation unit. By decoupling over the amplifier have the same area Segments on substantially the same capacity values, so that this each have the same low signal rise times.

The The invention will be explained below with reference to the drawings. It demonstrate:

1 : Schematic representation of the optoelectronic device according to the invention.

2 : First exemplary embodiment of the segment arrangement of the receiving element.

3 : Block diagram of the device according to 1 ,

4 : Reception element according to 2 with a subordinate addition and subtraction network.

5 : Truth table for scanning range switching for the addition and subtraction network according to 4 ,

6 Second embodiment of the segment arrangement of the receiving element.

7 Third embodiment of the segment arrangement of the receiving element.

1 shows the basic structure of an optoelectronic device designed as a light scanner 1 , The optoelectronic device 1 has a transmitter 2 on, which is preferably formed by a light emitting diode and which transmitted light beams 3 emitted. The transmitted light rays 3 be by means of a transmission optics 30 bundled. The optoelectronic device 1 also has a receiving light beams 4 receiving receiving element 5 on, wherein the received light beams 4 by means of a receiving optics 40 on the receiving element 5 be focused.

The of an object 11 reflected back receive light beams 4 meet the receiving element 5 which is a near element 5a and a remote element 5b having. In this case, the position of the light spot of the received light beams varies 4 on the receiving element 5 depending on the distance of the object 11 to the device 1 , At large distances, the received light almost completely hits the remote element 5b , With decreasing distance, the received light increasingly hits the near element 5a ,

The received signals at the outputs of the near and far elements 5a . 5b be in an evaluation unit 12 evaluated, to which the transmitter 2 and the receiving element 5 are connected. In this case, a binary switching signal is generated in response to the received signals and via a switching output 13 output. The binary switching signal is generated by means of a switching threshold, wherein the switching output 13 then the switching state changes when the object 11 in a distance corresponding to the distance to the device 1 located.

In a first embodiment, the difference in the received signals of the near and far element in the evaluation unit 5a , 5b educated. This difference is then evaluated with a threshold value S1 forming the switching threshold. The object 11 is within the range of the device 1 if the difference corresponds to the threshold value S1.

In a second embodiment, the quotient of the received signals is formed. This quotient is evaluated with a threshold value S2 forming the switching threshold. The object 11 is within the range of the device 1 if the quotient corresponds to the threshold value S2.

Conveniently, the quotient of the difference and the sum of the received signals of the near and far element 5a . 5b educated. Alternatively, by means of a transmission control, the sum of the received signals can be regulated to a constant value. By this signal evaluation, a signal independent of the object reflection switching signal is obtained. In addition, the quotient formation is considerably simplified by the return to a difference formation.

According to the invention, the photosensitive surface of the receiving element 5 into several segments 6 - 10 divided. The segments 6 - 10 are each formed by photodiodes. Every segment 6 - 10 is an amplifier 16 arranged downstream to amplify the respective output signals. These output signals are in the evaluation unit 12 logically linked, so that a given number of segments 7 - 10 the near element 5a forms and the remaining segments 6 - 8th the remote element 5b form.

The segments 6 - 10 are substantially coextensive and juxtaposed, arranged directly adjacent to each other, so that they complement each other to a seamless photosensitive surface. The longitudinal axis of this arrangement is substantially transverse to the optical axis of the received light beams 4 ,

2 shows a receiving element 5 , the photosensitive surface in five equal-area rectangular segments 6 - 10 is divided. The segment 6 forms the remote element 5b , the remaining segments 7 - 10 form the near element 5a , As the object distance becomes shorter, the light spot of the received light beams moves 4 from the segment 6 over the segments 7 - 10 ,

The distance-dependent spot position is exploited to the object to be detected 11 to distinguish from a background. This is the remote receive signal of the segment 6 with the sum of the near-receive signals of the segments 7 - 10 compared. Outweighs the near signal of the segments 7 - 10 , the object is valid 11 as recognized.

By changing the linkage of the individual segments 6 - 10 , a different near and far range can be defined and thus the range can be easily changed.

3 shows the block diagram of the device 1 according to 1 with the receiving element 5 ,

In this embodiment, the evaluation unit 12 from a processor with analog-to-digital converter. As a result, at the switching output 13 the switching signal is output. The evaluation unit 12 has a parameter input 14 via which the scanning distance, switching threshold and switching hysteresis are entered. These parameters allow an application-related adaptation of the device 1 , The parameter input 14 is there preferably formed as a serial interface. In particular, the parameters also determine the type of logical linkage of the segments 6 - 10 of the receiving element 5 specified. The parameter values are finally stored in a parameter memory 15 stored.

The analog-to-digital converter also allows the detection of measurement errors or disturbances by analyzing the level distribution across each segment 6 - 10 ,

4 shows a further embodiment of the receiving element 5 , where the amplifiers 16 at the outputs of the segments 6 - 10 an addition and subtraction network is arranged downstream. The arrangement of the segments 6 - 10 of the receiving element 5 corresponds to the arrangement according to 2 , To evaluate the received signals, it is advantageous analog preprocessing in the subtraction and addition network in the form of a sum and difference of the digital evaluation in the evaluation 12 upstream. In particular, an overload by high received signal level at highly reflective object 11 suppressed by the difference formation near the detection distance.

By means of the switches s1-s5, receive signals of different segments can be received 6 - 10 be combined.

5 shows the truth table for the scanning distance switching. Thus, with simultaneous over-irradiation of the Nah- and Fernelementfläche by the received light beams 4 an object 11 is safely detected, the Nahelementfläche must be larger than the Fernelementfläche. For this reason, the generation of the remote signal is always only one segment 6 . 7 or 8th selected, which is done with the switches s3-s5. For the near range, at least the signals of the two segments 9 and 10 in the summer 17 summarized. In addition, the advantage between the as a remote element 5b selected segment 6 . 7 and the segment 9 lying segments 7 . 8th with the help of the switches s1 and s2 the Nahelement 5a assigned. By subtraction of near and far signal in the subtractor 19 this occurs at the differential signal output 20 , pending difference signal from which the switching state of the sensor is derived.

In addition, via the summer 18 a sum signal at the sum signal output 21 provided that represents the total received power and can be used for transmitter control or quotient formation.

The at the difference signal output 20 and the sum signal output 21 Pending signals are for further evaluation in the evaluation unit, not shown 12 read, which can be suitably formed again as a processor. From the evaluation unit 12 leads a control input 22 to the addition and subtraction network. About this control input 22 will be in the rear derailleur 23 activated to confirm the switch. In this way, in turn, via the evaluation unit 12 the logical combination of the output signals of the segments 6 - 10 specified.

Another embodiment of the receiving element 5 is in 6 shown where the segment length is matched to the distance-dependent patch shift. As a result, almost equidistant scanning distance steps are achieved when switching the scanning distance.

Another embodiment is in 7 shown where the receiving element 5 is split longitudinally, so that mirror-symmetrical to the segments 6 - 10 each further segments 6 ' - 10 ' are arranged and thereby the lateral displacement of the spot can be detected.

• – Umspiegelung durch seitliche Objekte 11,
• – seitlich einfallendes Fremdlicht,
• – Verzerrungen durch Objekt-Oberflächenstrukturen

durchzuführen.This possibility can be exploited to check plausibility checks, such as

• - Reflection by lateral objects 11 .
• Lateral incident light,
• - Distortions by object surface structures

perform.

The longitudinal division of the segments 6 - 10 can also be used to detect the lateral object immersion direction, wherein during the immersion, the signal level of a segment side, for example 6 - 10 are much larger than those of the segments 6 ' - 10 ' ,

Claims (17)

An optoelectronic apparatus for detecting objects in a surveillance area having a transmit light emitting transmitter and a receive light receiving member comprising a proximity element and a remote element, the receive light beams reflected from the object first encountering the proximity element and then the far element with increasing object distance, and wherein in an evaluation unit in response to the received signals at the outputs of the near and far element, a binary switching signal is generated, characterized in that the receiving element ( 5 ) several segments ( 6 - 10 ) whose segment lengths correspond to the distance-dependent spot shift of the received light beams ( 4 ) on the receiving element ( 5 ) are tuned. Optoelectronic device according to claim 1, characterized in that a predeterminable number of segments ( 7 - 10 ) to the near element ( 5a ) and a predeterminable number of remaining segments ( 6 - 8th ) to the remote element ( 5b ) are connectable. Optoelectronic device according to claim 1 or 2, characterized in that the segments ( 6 - 10 ) of the receiving element ( 5 ) are substantially equal in area. Optoelectronic device according to claim 1 to 3, characterized in that the segments ( 6 - 10 ) are arranged side by side and the longitudinal axis of the arrangement substantially transverse to the optical axis of the incident receiving light beams ( 4 ) runs. Optoelectronic device according to one of claims 1 to 4, characterized in that the segments ( 6 - 10 ) are formed by photodiodes. Optoelectronic device according to one of claims 1 to 5, characterized in that each segment ( 6 - 10 ) a separate amplifier ( 16 ) is subordinate. Optoelectronic device according to claim 6, characterized in that the output signals of the amplifiers ( 16 ) via an analog-to-digital converter into an evaluation unit ( 12 ) are read in, and that in the processor, the output signals to the received signals of the Nah- and Fernelements ( 5a . 5b ) are logically linked. Optoelectronic device according to claim 6, characterized in that the output signals of the amplifiers ( 16 ) are fed to an analog addition and subtraction network, in which a predeterminable number of output signals can be linked by additions and / or subtractions, and in that the output signals thus obtained are fed into an evaluation unit ( 12 ) forming processor are readable. Optoelectronic device according to one of claims 1 to 7, characterized in that the evaluation unit ( 12 ) a configured as a serial interface parameter input ( 14 ), via which the type of linking of the segments ( 6 - 10 ) can be specified. Optoelectronic device according to one of claims 1 to 8, characterized in that the binary switching state via a to the evaluation unit ( 12 ) connected switching output ( 13 ) is output. Optoelectronic device according to claim 9, characterized in that at an object located in a predetermined range ( 11 ) the switching output ( 13 ) changes its switching state. Optoelectronic device according to claim 9, characterized in that in the evaluation unit ( 12 ) the difference of the received signals of the near and far element ( 5a . 5b ), and this difference is evaluated with a threshold value S1 forming the switching threshold. Optoelectronic device according to claim 10, characterized in that the difference of the received signals of the near and far element ( 5a . 5b ) corresponds to the height of the threshold S1 if the object ( 11 ) in a distance corresponding to the distance to the device ( 1 ) is located. Optoelectronic device according to claim 9, characterized in that in the evaluation unit ( 12 ) the quotient of the received signals of the near and far element ( 5a . 5b ) is formed and this quotient is evaluated with a threshold value S2 forming the switching threshold. Optoelectronic device according to claim 13, characterized in that the quotient of the received signals of the near and far element ( 5a . 5b ) corresponds to the height of the threshold, if the object ( 11 ) in a distance corresponding to the distance to the device ( 1 ) is located. Optoelectronic device according to claim 13 or 14, characterized in that the quotient of the difference and the sum of the received signals of the near and far element ( 5a . 5b ) is formed. Optoelectronic device according to claim 15, characterized in that by means of a transmission control, the sum of the received signals of the near and far element ( 5a . 5b ) is controlled to a constant value.