WO1980002324A1

WO1980002324A1 - Optoelectronic equipment for measuring and detection

Info

Publication number: WO1980002324A1
Application number: PCT/DE1980/000047
Authority: WO
Inventors: R Karg; C Jambor
Original assignee: Bbc Brown Boveri & Cie; R Karg; C Jambor
Priority date: 1979-04-14
Filing date: 1980-04-09
Publication date: 1980-10-30
Also published as: EP0027120A1; DE2915398A1

Abstract

A command and supervision equipment monitored by a microprocessor and intended for the optoeletronic recognition of models and positions, comprises a measuring and detection bus and a microbus to which are connected a unit for taking pictures, a microprocessor, an inlet keyboard, an apparatus for the determination of the centre of gravity, an outlet unit and a central clocking unit as well as an image calculator and an image memory.

Description

Optoelectronic measuring and sensor system.

The invention relates to an optoelectronic measuring and sensor system and is in the field of image and information processing for the optical acquisition and processing of image data, for example in industrial handling machines.

Arrangements and methods for recognizing objects of different dimensions are known. Control signals are formed after identification and position determination, for example for handling machines for gripping and further processing of the recognized objects. It is taught in DE-OS 24 43 265 that an unknown object can be recognized by imaging on photoelectric layers using translucent filters. Behind the filter there are light-sensitive layers that detect the different light permeability of the filter and, after electrical connection, a control signal for a handling machine, industrial robot or the like. form. By comparing the recognized object with characteristic values present in a data memory, a simplification or selection in the detection and detection of the objects is possible.

A method for identifying objects (DE-OS 27 49 682) by determining the area, scanning curve from the center of the image and further scanning data is also known. By comparison with corresponding stored reference parameters, an identification of the unknown object can be made possible. In many cases, the determination of the area is sufficient for a pre-sorting. The scanning curve from the center of the image is then used for an exact recognition and further scanning data for very difficult selection tasks.

Also known (DE-OS 27 48 604) is a method for determining the rotational position of unknown objects by optoelectronic scanning and determining the center of gravity. The object can be identified by comparing the scanning data with stored data of reference objects.

An automation system for the control and monitoring of production using image recorders, microprocessors and peripheral devices, as well as data exchange within the system via a bus line, has not yet been disclosed. A general data exchange system, which is also processor-controlled and has data and address bus lines, is known from DE-AS 26 02 459. However, the arrangement shown here is not used for optoelectronic image recording. It is therefore an object of the invention to find a processor-controlled control and monitoring system for optoelectronic pattern and position recognition, processing, visual inspection and contactless measurement technology.

According to the invention, this is achieved in that a recording unit, a microcomputer, an input keyboard, a module for determining the center of gravity, an output unit and a clock center are connected to a measuring and sensor bus, that an image computer and an image memory are connected to a μ-bus , and that the measuring and sensor bus is decoupled from the μ-bus via an interface.

Refinements of the optoelectronic measuring and sensor system can be seen from the subclaims.

The great range of uses for the peripheral devices to be connected is particularly advantageous in the system according to the invention. For example, by connecting additional recording cameras, a very quick position detection can be carried out in various processes using the multiplex method. The type of position detection can be freely selected. It shows a flexible, easily reprogrammable and inexpensive automation system for the control and monitoring of industrial processes with a standard TV camera. The system also has the ability to recognize patterns for sorting production parts or recognizing labels. The system is also modularly expandable and can therefore be adapted to special requirements in industrial production. Connected computers take over the image analysis, the processing of the data, the system administration and the communication with the peripheral devices. An embodiment is explained below with reference to the drawing.

A measuring and sensor bus system 1 and a μ-bus system 2 are separated by an interface 3 (decoupling and adaptation module). Each of these two bus systems can thus perform completely different tasks simultaneously and separately from one another. An image computer 4 and an image memory 5 are connected to the μ-bus system 2. The image computer 4 (for example a microprocessor) takes over the addressing of the image memory 5. The digital image memory 5 receives the data received from the television cameras and keeps them ready for further processing. Detecting objects that pass a camera on a conveyor belt is difficult because the camera must follow the movement of the object. Brief sampling and storage of the data in the image memory with subsequent evaluation from the image memory therefore enables the system to work quickly. The image memory 5 thus holds the acquired data ready for further analysis and the television camera can be aimed at a new object.

The image computer 4 scans the image recorded by the television camera in polar coordinates. However, it can also count certain brightness values when scanning the recorded image. Furthermore, he can measure lengths and transitions from black to white within the television picture. counting. The image computer 4 is thus used to analyze stored or acquired image information.

The measuring and sensor bus 1 has the task of supplying the image computer 4 and the image memory 5 with information. A recording unit 6 is connected to this bus. This recording unit can record the analog signals of several television cameras and emit signals for several television monitors. In an adaptation circuit within the recording unit 6, the analog signals of the television camera are digitized or converted into video signals for the monitors. A window discriminator is also arranged in the recording unit 6, which only allows a certain part to pass through the image to be scanned, and saves considerable computing effort due to this reduction. A video link circuit for comparing a recorded image with a stored image is also arranged in the recording unit. This target / actual comparison between the stored reference image and the image recorded by the camera and counting the differences makes it possible to achieve a further saving in computing capacity.

A microcomputer 7 is also connected to the measuring and sensor bus 1 via an adapter circuit. This microcomputer is used for general control of the system. Its task is e.g. in the correct switching of the cameras. For example, printers, interfaces to higher-level systems and the like can be connected to the microcomputer. Connections for a "floppy disc" (data storage disk) and an external program input device are also provided.

An input keyboard 8 for operating the entire system is connected to the adapter circuit of the microcomputer 7. This keyboard consists of controls with which e.g. the individual devices are switched on / off or on and off.

A module 9 for determining the center of gravity is connected to the measuring and sensor bus 1. Here the fundamental calculations for the detection of unknown objects by the surface moment in the x and y direction and the surface are carried out. Furthermore, an output unit 10 is connected to the measuring and sensor bus. This can be used, for example, to control externally switchable machines (handling machines, industrial robots). The output unit also has a programmable clock for a time / path clocking, as well as an additional control device for outgoing information.

A clock center 11 is connected to the measuring and sensor bus 1 in order to synchronize the entire system. Clock or synchronization pulses are used for the precise interconnection of the individual system modules with each other, but the television cameras and monitors are also acted on with the synchronization pulses. The clock center also supplies a trigger signal for an externally connectable flash light. This illuminates the object to be recognized for a short time (snapshot) so that the television camera can then scan the recorded image in a cell-like manner. In this way, blurring (for example, with moving objects) can be avoided when taking pictures. The clock center 11 also has a trigger input for external synchronization. A pulse for such an input can be generated by a light barrier. This trigger pulse triggers the externally connectable flash light, for example, which initiates the detection process.

In an embodiment of the system according to the invention, a further module for determining the center of gravity can be connected to the measuring and sensor bus for a quick determination of the position. The television cameras connected to the recording unit 6 can only deliver their information serially to the modules for further processing. Thanks to the additional module for determining the center of gravity, two cameras are given information at the same time, which can advantageously accelerate the processing of several measuring points (television cameras). This component is not shown in the drawing.

Claims

Expectations

1. Optoelectronic measuring and sensor system, characterized in that on a measuring and sensor bus (1) a recording unit (6), a microcomputer (7), an input keyboard (8), a module (9) for determining the center of gravity, an output unit ( 10) and a clock center (11) are switched on, that an image computer (4) and an image memory (5) are connected to a μ-bus (2), and that the measuring and sensor bus (1) is connected by the μ- Bus (2) is decoupled via an interface (3).

2. Measuring and sensor system according to claim 1, characterized in that the image computer (4), the image memory (5) and the interface (3) can be optionally switched on.

3. Measuring and sensor system according to claim 1, characterized in that the recording unit (6) has connections for television cameras and monitors, and that in the recording unit (6) a window discriminator for an adjustable picture frame and a linking unit for

Comparison of a recorded and stored image is arranged.

4. Measuring and sensor system according to claim 1, characterized in that printers, data storage disks, program input devices and interfaces to higher-level systems can be connected to the microcomputer (7).

5. Measuring and sensor system according to claim 1, characterized in that the output unit (10) processing systems, a programmable clock for a time / distance clocking and a control device for outgoing information can be switched on.

6. Measuring and sensor system according to claim 1, characterized in that from the clock center (11) a plurality of sync pulses and a trigger signal for a flash trigger are removable and that external triggering of the clock center is possible.

7. Measuring and sensor system according to claim 1, characterized in that further modules for determining the position of unknown objects on the measuring and sensor bus (1) can be switched on.