KR0148447B1 - Measuring equipment and method of distance using laser beam scanner - Google Patents

Abstract

In the optical distance measuring apparatus using a laser, in particular, by measuring the distance between the laser beam to make a parallel beam and scanning by scanning method, it is characterized in that to improve the loss rate of the signal and the accuracy of the measurement error The present invention relates to a distance measuring device and method using laser beam scanning, and a conventional optical distance measuring device scans a laser at a predetermined angle when emitting a laser, thereby causing an error in distance according to the intensity of light within a predetermined distance. In addition, there is a disadvantage in that the data loss rate is increased due to the delayed light emission period, the present invention is formed by narrowing the scanning angle of the laser beam to make a parallel light, the same distance by scanning a certain angle by scanning in several tens of KHz Increasing the accuracy of the distance error measured by the reflection on the object in the It will allow you to quickly reduce the loss modulus of the data.

Description

Distance measuring device and method using laser beam scanning

1 is a laser beam emission degree scanned at a constant angle.

Figure 2 (a) is an ideal laser beam cross section, (b) is an actual laser beam cross section.

3 is an overall configuration diagram of the present invention.

4 is a laser beam emission degree in which parallel light is scanned at a constant angle.

5 is a flowchart illustrating a distance measuring method using laser beam scanning according to the present invention.

* Explanation of symbols for main parts of the drawings

10: control unit 20: pulse generator

30: laser light emitting unit 40: laser light scanning unit

50: laser diode error detection unit 60: laser receiver

70: received signal processing unit 80: display unit

The present invention relates to an optical distance measuring apparatus using a laser. In particular, by measuring the distance between the laser beam by making a parallel beam and scanning by scanning method, it is possible to improve the signal loss rate and the accuracy of the measurement error The present invention relates to a distance measuring apparatus and method using laser beam scanning.

In general, most conventional distance measuring devices have a method of measuring a distance from an object with a standard measuring equipment of a corresponding length.

On the other hand, in the optical distance measuring device, the distance measuring method measures the distance using the measured travel time and the light beam by measuring the time the light traveled.

However, the conventional distance measuring device using the light is scanned at a predetermined angle when the laser emits light, an error occurs according to the intensity of the light, and also a problem that the data loss rate is increased due to the slow speed of the light emission cycle. there was.

That is, the cross-section of the laser output when the laser is scanned at a predetermined angle as shown in FIG. 1 does not have an ideal rectangular structure distribution as shown in FIG. 2 (a) but is actually a Gaussian (B) as shown in FIG. GAUSSIAN) distribution. Because the data reception rate decreases when the laser emits light at a narrow angle in order to maintain the ideal rectangular structure distribution, the laser beam output has a strong center because the laser beam must be scanned at a certain angle to widen the distribution of the laser beam in order to maintain the proper reception rate. The part and the weak part appear, so the distance error occurs when measuring the same distance.

The present invention is to solve this problem of the prior art, in particular, characterized in that to improve the accuracy of the signal loss rate and measurement error by scanning the parallel light laser beam at a certain angle of several tens of KHz.

In other words, by narrowing the scanning angle of the laser beam to make parallel light, scanning by scanning a certain angle at several tens of KHz to improve the accuracy of the distance error measured by reflecting to the object at the same distance and to speed up the emission period of the laser This will reduce the loss of data.

Hereinafter, described in detail with reference to the drawings.

3 is an overall configuration diagram of the present invention, the control unit 10 for controlling the entire system; A pulse generator 20 for generating a high voltage by using a DC level converter and a transformer and applying a pulse of several tens of ns to the laser; A laser light emitting unit 30 which emits a laser to the target object 1 according to an operation signal of the pulse generator 20; A laser beam scanning unit 40 scanning the laser beam to be scanned at a predetermined angle from side to side using an oscillator; A laser diode error detection unit (50) which monitors whether the laser emits light and an abnormal output and transmits the signal to the control unit (10) to stop the laser light emission with an alarm; A laser receiver 60 for receiving the reflected light; A received signal processor 70 for processing the received signal and applying the received signal to the controller 10; The display unit 80 is configured to notify the driver of the measured distance data.

The present invention configured as described above has a light output as shown in FIG. 2 (a) by using a lens when the laser emits light to the object by the pulse generation signal of the controller 10, and the prism in the laser light scanning unit Using a reflector that can reflect light, the light is scanned using an oscillator that spreads the light at an angle, that is, left and right. Therefore, the laser measuring apparatus of the present invention scans from side to side using an oscillator while maintaining the laser beam scanning angle of a narrow distribution as shown in FIG. In this case, the emission speed should be faster than that of the laser used in the same manner as in FIG. For example, if the emission rate is 10ms when the laser is fired by the method shown in FIG. 1, the method of FIG. 4 uses more than 10 times (1ms). That is, in the method as shown in FIG. 4, when the laser beam emits light from several KHz to several tens of KHz, a better measurement distance can be obtained.

On the other hand, the laser light emitted to the target object by scanning the laser light emitted at a narrow angle as described above is input to the laser receiver 60, is converted into the distance data by the reception signal processing unit 70 is output to the controller 10 This is displayed on the display unit 80.

Referring to the operation of the present invention, the control unit outputs a laser emission signal, and if there is no emission by using a device for monitoring the error of the laser beam emission, and transmits an error for it to the control unit, and if there is no error start the laser emission Use as a signal. And if there is an input signal of the light receiver, the distance is calculated. When 100 distance measurement data is accumulated, the distance is calculated by using the standard deviation and the average to make one distance data and transmitting it to the controller.

5 is an operation flowchart of the present invention, by checking whether the trigger signal is output (S1), and when the trigger signal is output in the trigger signal on step (S1), it is determined whether the laser emits light (S2), and the laser light emission. If the laser is not emitted in the determination step (S2), it is output to the controller that an error occurs in the laser diode (S3).

In addition, when the laser light is emitted in the laser emission determination step (S2), it is determined whether a received signal is input (S4), and when the received signal is not input in the received signal input determination step (S4), the trigger signal on step Returning to step S1, if a received signal is input, the distance is measured (step S5).

If the distance is measured in the distance measuring step S5, it is determined whether the distance measurement data is accumulated by the set value (S6), and the distance measurement data is not accumulated by the set value in the distance measurement data determination step S6. If so, the process returns to the trigger signal on step S1, and if accumulated, the accumulated distance data is converted into single distance data and output to the distance display unit (S7).

As described in detail above, the present invention improves the loss ratio of the signal and the accuracy of the measurement error by scanning the laser beam at a constant angle with parallel light.

Claims (2)

A control unit 10 for controlling the entire system; A pulse generator 20 for generating a high voltage by using a DC level converter and a transformer and applying a pulse having a predetermined size to the laser; A laser light emitting unit 30 which emits a laser to an object in accordance with an operation signal of the pulse generator; A laser beam scanning unit 40 scanning the laser beam to be scanned at a predetermined angle from side to side using an oscillator; A laser light error detecting unit (50) for monitoring whether the laser emits light and an abnormal output, and transmitting an abnormality to the control unit to stop the laser light emission with an alarm; A laser receiver 60 for receiving the reflected light; A received signal processor 70 for processing the received signal and applying the received signal to the controller; Distance measuring device using laser beam scanning, characterized in that it comprises a display unit for displaying the measured distance data to the driver (80). A trigger signal on step S1 for checking whether a trigger signal is output; A laser emission determining step (S2) of determining whether or not the laser emits light when the trigger signal is output in the trigger signal on step (S1); An error generation output step (S3) of outputting, to the controller, an error in the laser diode if the laser is not emitted in the laser emission determination step (S2); A reception signal input determination step (S4) of determining whether a reception signal is input when the laser light is emitted in the laser emission determination step (S2); A distance measuring step (S5) of returning to the trigger signal on step (S1) if the received signal is not input in the received signal input determining step (S4) and measuring a distance if the received signal is input; A distance measurement data determination step (S6) of determining whether distance measurement data is accumulated by a set value when the distance is measured in the distance measurement step (S5); If the distance measurement data is not accumulated by the set value in the distance measurement data determination step S6, the trigger signal and the step S1 are returned. If the distance measurement data is accumulated, the accumulated distance data is converted into a single distance data to be displayed on the distance display unit. Distance measuring method using laser beam scanning, characterized in that it comprises a distance data transmission step (S7) for outputting.