DE4005919C1 - Ascertaining range of vision of car driver in fog - using range finder transmitting signals and receiving those reflected from road surface not covered by fog - Google Patents

Abstract

A distance-measuring device (2) consisting of a transmitter and a receiver is fastened at the front of a car (1) so that it can be swung, in equal steps, a to j, over the length being measured, immediately in front of the car by moving in a vertical plane. The signals transmitted from the device however are reflected back from the points on the road (3) to the receiver only when they are not concealed by fog (5). When the road is covered by fog, signals do not return to the receiver. USE/ADVANTAGE - Ascertaining visibility in fog using mostly readily available equipment.

Description

The invention relates to a method for determining the view wide for motorists when fog occurs according to the generic term of claims 1 and 2 and an arrangement for performing this Procedure.

DE 22 23 230 C3 describes a method for monitoring the permeability The atmosphere is known, with the distance along a highway from about 50 to 150 m several each with transmitter, receiver and warning board equipped measuring points are provided for corresponding displays. Channel and the receiver of a measuring point point in the opposite direction and each communicate with the receiver or transmitter of the next measuring point. The signal is here from a light source, preferably one in luminescent diode working in the infrared range. The one on the way from the transmitter of one measuring point to the receiver of the next measuring point damping of the electromagnetic radiation caused by fog is ge measure up. Then the frequency of this radiation in each measuring section set by damping the previous section and close Lich the attenuation and the frequency of the radiation in one be agreed a measuring section appearing at the beginning of each measuring section Display derived, the information about any change in through atmosphere of the previous section. Such the system, which functions reliably, is localized and because of its Expenses can only be used in certain, particularly fog-prone areas.

DE 32 15 845 C1 and EP 00 92 825 A2 show and describe in FIG. 7 a receiver consisting of several channels of a distance sensor for projectile detonators. This distance sensor is equipped with a laser rangefinder based on the pulse transit time method, the transmitter of which emits pulses in the direction of the target. It also contains a large number of receiving diodes corresponding to the number of measuring points, which convert the pulses reflected from the target into electrical signals. Then it contains a scanning circuit which synchronizes with the transmission pulses, compared to these, however, briefly trained and delayed in a predetermined manner, scanning the received signals. In this way, in the event of a relative movement between the sensor and the target and the associated phase shift between received signals and needle pulses, a sequence of sampled values is generated which represent the amplitudes of successive received signals at different times of these signals. For the monitoring of a distance range, a phase modulation of the needle pulse is then necessary, as can be seen in FIG. 8 and the associated description of both documents. The pulse generator can be used as a trigger for a mono flop stage, the time constant of which is varied by a modulation voltage. The needle pulse is then obtained from the trailing edge of the monoflop pulse. This technique is used in the present invention.

The object of the invention is for the driver with largely conventional means to create an opportunity for people with visual impairments Fog to be able to estimate the existing visibility. This task will according to the invention by those mentioned in process claims 1 and 2 Features and with respect to the arrangement by claim 6 ge solves. Such a possibility, which, if necessary, also goes as far allows to expand the relative speed to a previous one Vehicle detection is not yet on the market.

Further advantageous embodiments result from the subclaims.

In the following, embodiments of the He Finding explained in more detail, the ent in the individual figures speaking parts have the same reference numerals. It shows

Fig. 1 is a schematic diagram of the inventive method,

Fig. 2 shows the timing diagram of a conventional scanning method used in the RF oscillograph by means of a spike,

Fig. 3 shows the block diagram of the receiver with simultaneous irradiation of several measuring points of the pavement and

Fig. 4 shows the block diagram for the irradiation of an entire distance range.

In the front area of the car 1 of FIG. 1 is an existing transmitter and receiver and working according to the pulse transit time range meter 2 , the z. B. can be a laser rangefinder attached. This rangefinder is aligned with the road surface 3, which is divided into equi-distant steps a to j on a corresponding panel, and can be pivoted in the hinge 4 by angle α in elevation, either continuously or stepwise. The same movement can be carried out in many cases, mostly even more elegantly, by means of a scanning mirror, which is not shown here in the drawing. As long as in such a pivoting operation, the road surface 3 reflects a sufficiently high signal to the receiver in all positions of the rangefinder, the range, which corresponds approximately to the range of vision, is greater than the entire measuring distance j, so that the driver can drive freely. On the other hand, only reflects the signal from point a, for example, because the car is approaching the smoke screen 5 , this means that the visibility is already smaller than the measuring distance b and the driver must therefore be extremely careful.

In another embodiment, not shown in the drawing, a plurality of range finders 2 can also be mounted in the front area of the car 1 above one another and with different, but stepped inclination angles α to the road surface 3 . In this case, several measuring beams are emitted at the same time, so that the same information results for the driver in the end. It is obvious that both variants shown only work if the road is running straight in front of the vehicle in the range of the measuring distance. The driver may therefore only sensibly operate the device if he believes that he is on a straight stretch of the road.

If necessary, a measurement of the relative speed between the car 1 with its range finder 2 and the target can also be combined with the visibility measurement described so far. In this case, all measurements aligned to the road surface 3 using the Doppler effect then show the vehicle speed. However, if there is an obstacle 5 between the rangefinder and the road surface, this obstacle determines or displays the visibility and the relative speed of one's own car in relation to this obstacle - provided sufficient visibility is required. This means that the relative speed of vehicles in front can also be determined in this way with the range finder in the absence of fog.

However, since complete laser rangefinders are still comparatively expensive as a mass-produced product in the auto industry, a range of vision measurement - which is still sufficiently accurate for the intended purpose - is possible with the following device components using the optoelectronic method according to DE 32 15 845 C1 and EP 00 92 825 on: A signal whose repetition frequency is known is to be received in FIG. 2a. For this purpose, a receive key or needle pulse 8 (also called sampling pulse in laboratory jargon) is generated according to FIG. 2b, which has the same sequence frequency as the signal pulse to be received, but is phase-modulated with respect to this. As a result, it coincides with another instantaneous value of the signal pulse from period to period. About a diode - these are the sampling diodes 6 to 6 ^X of Fig. 3 - both pulses, signal pulse 7 and needle pulse 8 , on a capacitor - in Fig. 3, the capacitors 9 to 9 ^X - so that at the output of the between the diode and the capacitor connected amplifier - in FIG. 3 the positions 10 to 10 ^X - the sawtooth voltage 26 shown in FIG. 2c arises, the peak amplitude of which corresponds to the sum of the two instantaneous values. If the input signal were zero, a voltage curve according to FIG. 2d would result. In the presence of the signal pulse, a low-frequency signal 29 is generated, which corresponds to a temporally stretched original pulse according to FIG. 2e. What is said in this paragraph is state of the art and only serves to explain the so-called sampling method, which is used as part of the present invention as follows: Should z. B. Visibility up to about 100 m can be assigned, according to FIGS. 1 and 3, the ten measuring points a to j of the road surface 3, ten reception channels 11 to 21 , the associated needle pulses 8 of which are delayed relative to the transmission pulses 7 so that they coincide with the transmission pulses reflected from a distance of 10, 20, 30 ... 100 m. If the measuring beam of the transmitter containing the transmission signal is now deflected via a scanning mirror (not shown in the drawing) in such a way that it first hits the road surface 3 at a distance of 100 m and then comes closer and closer by tilting the mirror, the needle pulse is successively transmitted via the received pulses 7 'of the ten channels 11 to 21 run, each channel reporting the arrival of its needle pulse. The otherwise necessary phase modulation of the needle pulse is not necessary here. Monitoring electronics now only need to determine which channel has received signals.

The electronics required for this and for understanding is again part of the aforementioned sampling method and is therefore not the subject of the invention. Here, the pulse generator 22 ( FIG. 3) generates a voltage, so that the transmitter diode 31 emits the signal pulse 7 ( FIG. 2) after optoelectronic conversion. A small part of the pulse-shaped driver voltage is decoupled and, after passing through the delay elements 24 to 24 ^{X, is used} as a needle pulse 8 according to FIG. 2b. The delay times 25 ( FIG. 2) are set so that they correspond to the path to be detected in advance of the signal pulses from the transmitting diode 31 to the destination, that is to say the roadway ceiling 3 , and back again to the receiving diode 30 .

If a car 1 equipped with such a sensor travels along a road, no signal is received as long as it cannot meet the needle pulse 8 . As a result of the movement of the scanning mirror, the signal reflected by the road surface 3 runs over the needle pulse with the mirror movement and is scanned by the latter.

In order to determine the relative speed mentioned above, the device must be switched to another operating mode. The scanning mirror stands still in the position that corresponds to the furthest distance. Now only one of the ten reception channels 11 to 21 needs to be used. For this purpose, a phase modulation of the needle pulse 8 according to FIG. 4, which is also taken separately from DE 32 15 845 C1 and EP 00 92 825 A2, is necessary. The pulse generator 22 can be used as a trigger for the monoflop stage 27 , the time constant of which is varied by a modulation voltage of the modulation generator 28 . The needle pulse is then obtained again from the trailing edge of the monoflop pulse. The area to be monitored can be set as required. It can be set from point "a" up to the maximum range "j" or to a range between two distances. Depending on the specification, either the pulse width is measured or several distance measurements are carried out, in which case the differences in the individual distances must be measured. In the first case, the envelope of the signal contains the information about the relative speed sought, while in the second case it results from the distance and time measurement that has taken place.

In a further embodiment, not shown in the drawing, the scanning mirror can be replaced in the following way: With any optical means, for. B. a cylindrical lens, transmit and receive beam are expanded in the vertical direction so that all ten measuring points a to j are detected. A chopper is arranged in front of or behind the optics, which modulates the transmit or receive beam in a simple manner in such a way that a yes / no statement about possibly in in every 10 channels ( 11-21 ) in a 100 Hz rhythm Obstacles existing on the measuring section arise.

Claims (9)

1. A method for determining the visibility for drivers when fog occurs using a transmitter consisting of a transmitter and receiver, characterized in that the distance meter ( 2 ) in the front area of a car ( 1 ) attached, via a in equidistant steps a to j divided, lying directly in front of the car, the elevation is pivoted and the signal sent out is only reflected at the measuring points covered by the fog ( 5 ) of the road surface ( 3 ) and not towards the receiver. 2. A method for determining the visibility for drivers when fog occurs using a rangefinder consisting of transmitter and receiver, characterized in that in the front area of a car ( 1 ) several rangefinders ( 2 ) with different inclination angle α to the road surface ( 3 ) one above the other fastened horizontally and at the measuring points a to j of a measuring section divided into equidistant steps, lying directly in front of the car, several signals are emitted at the same time so that they are not reflected only at the measuring points of the pavement covered by the fog ( 5 ) and not to the associated receiver. 3. The method according to claim 1 or 2, characterized in that a range finder ( 2 ) is used coupled with a speedometer with which, using the Doppler effect with a clear view, the relative speed to an obstacle ( 5 ) located between the range finder and the road surface ( 3 ) is measured. 4. The method according to claim 1 or 2 and using a be known distance sensor, which is composed of

• a transmitter for emitting transmission pulses,
• - A sampling circuit for sampling the received signals ( 7 ') by synchronized with the transmit pulses ( 7 ), but compared to these delayed in a predetermined manner,
• - The number of measuring points a to j corresponding to many sampling diodes ( 6 'to 6 ^X ) for converting the vision pulses converted by the receiving diode 30 into electrical RF signals into low-frequency pulse images ( 29 ),

characterized in that

• a) the transmit and receive pulse ( 7 ; 7 ') is steered with the aid of a scanning mirror over the measuring points a to j of the road surface ( 3 ) which are spaced apart from one another at equidistant intervals - starting from the remotest to the closest or vice versa,
• b) the scanning or needle pulses ( 8 ) compared to the transmission pulses ( 7 ) are delayed Lich so that they coincide with the transmission pulses reflected from the measuring points a to j of the pavement ( 3 ) and
• c) to determine the range of vision by means of monitoring electronics, the channels ( 11 to 21 ) are determined that have still received signals.

5. The method according to claim 4 and using a pulse generator ( 22 ) as a trigger for a monoflop ( 27 ), the time constant of which is varied by the voltage of a modulation generator ( 28 ), the needle pulse ( 8 ) being obtained from the trailing edge of the monoflop pulse, since characterized in that to determine the Relativge speed of the scanning mirror stopped, only one receiving channel is used, the needle pulse ( 8 ) phase-modulated and from the envelope ( 29 ) of the low-frequency pulse image the information for the Relativge speed is obtained. 6. Arrangement for performing the method according to any one of the preceding claims, characterized in that in the front region of a car ( 1 ), preferably above its front window, a range finder ( 2 ) which is pivotable in elevation about a joint ( 4 ) is arranged, the transmitter of which the roadway ceiling ( 3 ) divided into equidistant steps a to j is illuminated in such a way that a signal not shadowed by obstacles ( 5 ) reflects the signal onto the receiver. 7. Arrangement according to claim 6, characterized in that the range finder ( 2 ) is rigidly arranged and either a scanning mirror or a radiation widening over the equidistant steps a to j means z. B. a cylindrical lens, optically upstream and in the event that the scanning or needle pulses ( 8 ) compared to the transmission pulses ( 7 ) are delayed so that they with the from the measuring points a to j of the pavement ( 3rd ) reflected transmission pulses coincide, a chopper on all reception channels ( 11 to 21 ) results in a yes / no statement. 8. Arrangement for performing the method according to any one of claims 1 to 5, characterized in that in the front region of a car ( 1 ), preferably above its front window, several distance meters with different inclination angles α to the roadway ceiling ( 3 ) are arranged one above the other, the Transmitter illuminate the road surface ( 3 ) divided into equidistant steps a to j so that only the signals not shadowed by obstacles ( 5 ) reflect signals on the receiver.