DE2427623A1 - Visual range measuring device - has an optical directional device which passes only parallel rays or rays within a limited angle - Google Patents

Abstract

The device has a photosensor and an electric display unit, with the directional device before the sensor. It accepts only rays from a particular direction. The directional device consists of a tube with a collector and a pinhole stop at the collector focus, with the photosensor behind it. Two photosensors may be exposed to outside light, and an outer light source at a certain distance illuminates in addition one of these sensors connected in a bridge balancing out the effect of the outside light, with the display unit in the bridge detector diagonal.

Description

Visibility measuring device The invention relates to a visibility measuring device with a photosensor acting on an electrical display device.

The objective determination of visibility is common in many areas of great importance and in general cannot with sufficient certainty and accuracy can be made with the human eye. The human eye is known to convey subjective sensations that occur in the brain as a result of experience and other perceptions must first be evaluated. For example, has showed in road traffic that a rapid change in weather conditions and thus also the visibility of the vehicle driver in general only after a certain adjustment time to a change the behavior of the driver. This applies to both long-term and short-term Weather changes.

The long-term periods of good weather tempt the driver to drive at higher average speeds. He has become in his whole Driving behavior adjusted to these road and weather conditions. The experience shows that in the event of a sudden change in weather, rain or fog regularly occurs there has been a sharp increase in rear-end collisions. The adaptation of behavior The driver follows the new road and weather conditions a delay because the driver does not have an objective measure of the deterioration the road conditions are available, and because he is the new conditions only adjusts again on the basis of practical experience.

Short-term weather changes are rain, fog or thunderstorms that occur suddenly during the day. In these cases it will be Drivers very often overestimate visibility.

In addition, the brightness is not necessarily a measure of the range of vision represents. In the case of high brightness, this can be due to scattered light through fog or the like. Poor visibility.

However, it appears that the brain grows larger when it is registered Concluding brightness values at the same time on good visibility conditions - an association, the often does not apply.

A vision measuring device that is able to determine the prevailing It would not be possible to objectively determine the range of vision with little technical effort can only be used to increase safety in road traffic, but also for example in aviation, shipping, sports competitions and the like.

The object of the invention is to create a visibility measuring device, that can be realized with simple technical means and is valuable to the user Able to give information for his behavior.

To solve this problem it is proposed according to the invention that in front of the photosensor an optical straightening device is arranged, which only such light rays to the photosensor, which from a certain direction parallel or from a come up with a limited angular range.

In the case of the visibility measuring device according to the invention, between the following two types can be distinguished: 1. The first (simpler) type is only applicable in connection with headlights in the dark and measures that from the Surroundings reflected spot light.

2. The second type can be used in all lighting conditions. He completely or partially eliminates the influence of brightness through compensation, and determines by determining the scattering properties the path of a reference light beam the visibility.

The first type used in conjunction with headlights has a photo sensor that uses the upstream optical straightening device to generate the detected area illuminated by one or more headlights. Is the visibility meter attached to a motor vehicle, then the photosensor picks up on the surroundings reflected headlights. The amount of light received would result, for example a certain average value in dry surroundings and normal road conditions. When it is foggy, the headlights are heavily scattered and appear to a far greater extent thrown back the photosensor than in dry conditions. The photosensor therefore becomes a register high light intensity. Taking into account that the driver's presence von Nebel has recognized in principle, the measure is that which is recognizable on the display device Light intensity at the same time a measure of the density of the prevailing fog. The same is the case, for example, when blowing snow.

When it rains, it is well known that the headlights come from the surroundings only very poorly reflected. The visibility is low. The fact that on the display device If only a small amount of reflected light is displayed, the driver will recognize it in the In individual cases, how poor the visibility is.

The scale of the display device can facilitate the evaluation the display directly show information for the driving behavior, e.g. maximum permissible Speed, braking distance, switching on lights or Turn on the fog lights included. Of course, the Visibility can be displayed on the instrument panel.

The straightening device expediently consists of a tube, the one Contains a collector and a perforated diaphragm located approximately in the focal point of the collector, behind which the photo sensor is arranged. In many cases the optical Directivity of a simple tube, which is blackened on its inner wall, is sufficient, however, the directional sensitivity can be increased considerably by the aforementioned measure, so that in the borderline case only light incident exactly parallel to the tube at the photo sensor is registered.

A straightening device with tube, collector and perforated diaphragm is used preferably used in the second type of visibility measuring device according to the invention.

This second type is characterized in that it has two photo sensors exposed to the incidence of external light that on one of the photosensors In addition, a light transmitter arranged at a distance acts, and that both sensors in a compensation circuit that compensates for the influence of external light are interconnected.

The light transmitter, together with one of the photo sensors, forms a reference measuring section. It constantly emits light with a constant intensity. This light comes together detected with the external light of the environment by the photosensor. The influence of brightness of the outer The light is switched off by the fact that he is affected by the second Sensor measured and eliminated from the signal of the first photo sensor. For the The measurement result remains the intensity of the determined at the first photosensor reference light emitted by the light transmitter. It prevails on the reference measuring section between the light transmitter and the first photo sensor fog or rain, then that will The light from the light source is scattered and does not fully pass through the optical straightener through to the first photo sensor.

A bridge circuit can be used to compensate for the external brightness can be used in whose bridge zero branch the display device is located, but it is also possible, for example, to use a differential amplifier at its inputs the signals of the first and the second sensor with different signs issue.

The invention is described below with reference to the figures some preferred embodiments explained in more detail.

Fig. 1 shows schematically the structure of a viewing device from the first Type, Fig. 2 shows schematically the structure of a viewing device of the second type, Fig. 3 shows one possibility of the structural design of the straightening device for filtering exactly parallel incident light, Fig. 4 shows one with photo elements equipped bridge circuit, Fig. 5 shows a bridge circuit equipped with photo resistors, and FIG. 6 shows a further development of the bridge circuit according to FIG. 5.

The visibility measuring device shown in FIG. 1 has a tube 10 on, which is closed at one end and opened at the other end is. The inside of the tube is located near the closed end face 10 a photosensor 11. A number of light-sensitive components can be used, for example photo elements, photo resistors, photo diodes, photo transistors and similar.

The length of the tube 10 results in connection with the tube width and the position of the photosensor 11 the angular range 12 in which the measuring device radiation perceives. When attaching the visibility measuring device to a motor vehicle you ensure that the angular range 12 is approximately with that of the vehicle headlights the painted lighting area. The photosensor 11 therefore determines the amount of light from the surroundings that is illuminated by the vehicle headlights is, is reflected to the vehicle and generates an electrical accordingly Signal that is amplified in amplifier 13 and fed to display device 14.

The display device 14 consists of a voltage or ammeter, which is provided with a calibrated scale 15 within sight. The one when it is dry The vicinity of the reflected light amount registered by the photosensor 11 represents the pointer of the instrument 14 approximately in the middle position (normal). However, the light intensity is less than normal, e.g. - when it rains, the pointer shows this deterioration in numerical values so that the vehicle driver can adjust to it.

In the same way, the density of fog will lead to an increase the amount of reflected light is gradually detected. Even Yerstandlflch shows that Does a strong light work even in strong sunshine. The driver but then knows without further ado that it cannot be a question of fog.

In the case of the second type of visibility measuring device shown in FIG a first sensor 11 is accommodated in a tube 10 in the same way as in FIG Fig. 1.

In addition, a second sensor 16 is provided, which is in another Tube 10 is arranged in the same way. The outputs of the photo sensors 11 and 16 are connected to the complementary inputs of a differential amplifier 17. Of the The output of the differential amplifier 17 is connected directly to the measuring instrument 18.

Both photosensors 11 and 16 are exposed to external light exposed in the same way. So if only the outside light acts on both, then both signals cancel out at differential amplifier 17 and the display device 18 does not turn out.

At a distance in front of the photosensor 11 is made up of a lightbulb and a Parabolic mirror existing light generator 19 arranged. This can also be done by a Be surrounded by the tube. The rays of the light generator 19 are directly in the tube 10 directed into it, but it must be ensured that the light transmitter 19 the opening of the tube 10 is not shaded.

The actual measuring section lies between the light transmitter 19 and the Photosensor 11. If there is fog or moisture here, it will be detected by the light transmitter 19 incoming light is scattered and does not reach the photo sensor 11 in a bundled manner the signal from this photo sensor is weakened, resulting in a signal imbalance at the differential amplifier 17 leads. The amount of light scattering is therefore determined by the display device 18 displayed.

To increase the directivity of the straightening device, so that for example only light from a very specific direction penetrates to the photo sensor, can to train the straightening device in the manner shown in FIG. In the tube 10 is located with the photosensor 11 housed at its closed end a collector 21 is set back slightly compared to the open end 20, e.g. in the form of a converging lens with a large focal length. In the focal point of the collector 21 is the hole of a perforated diaphragm 22, which is also arranged in the tube is. The light reaches the photosensor 11 through this hole in this way that only such light affects the photosensor 11 that is exactly in Axial direction of the Tube collapses.

4 to 6 show various options for interconnection shown by photo sensors to a bridge circuit. The bridge circuit takes over here partly the function of the amplifier 17 in FIG. 2.

In the embodiment of FIG. 4, there are photosensors 21, 22 from photo elements. An external power supply is not required. The photo elements are in one branch of the bridge, while the other branch of the bridge is formed by a potentiometer 23, the tap of which leads to the bridge zero branch. The display device 18 is located in the bridge zero branch together with a further potentiometer 24.

The calibration of the display device takes place with full illumination of the Photo elements 21, 22. The change in the illuminance of the light transmitter 19 on the photo element 21 is already through coordination of the display device 18 by the Potentiometer 24 is done beforehand.

Depending on the weakening of the luminous flux from the light generator 19, a corresponding pointer adjustment of the display device 18, which then the visual state indicates.

The circuit of FIG. 5 is essentially the same as that of FIG. 4, except for the fact that instead of the photo elements 21, 22 photo resistors 25, 26 are used. Since these are purely passive components, must the bridge circuit can be connected to a voltage source 27.

The circuit of FIG. 6 is similar to that of FIG. 5, with the exception the fact that another photosensor 28 in series with the display device 18 in Bridge zero branch is located. The advantage of this circuit is that the entire Voltage level that is applied to the display device with the changed daylight brightness also changes, so that the device beyond the display of the visibility conditions can also display the effective brightness.

In the circuit diagrams of FIGS. 4 to 6, the optical straightening devices were used omitted for reasons of clarity. You have to be with that person Photosensor be present on which the light transmitter 19 acts. With the second photo sensor this is not strictly necessary, but should be for the sake of relief of the signal comparison may also be the case here.

Claims (4)

Expectations 7) -. Visibility measuring device with an electrical display device Acting photosensor, that is, that before the Photosensor (11) an optical straightening device (10) is arranged, which only such light rays to the photosensor, which from a certain direction parallel or from a come up with a limited angular range. 2. Visibility measuring device according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the straightening device consists of a tube (10) which has a collector (21) and a perforated diaphragm (22) located approximately at the focal point of the collector, behind which the photosensor (11) is arranged. 3. Visibility meter according to claim 1 or 2, d a -d u r c h g e it is not indicated that two photosensors (11, 16; 21, 22; 25, 26) correspond to the incident the external light are exposed that on one of the photosensors in addition at a distance arranged light transmitter (19) acts, and that both sensors in one Compensating circuit interconnected to compensate for the influence of external light are. 4. Visibility meter according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the compensation circuit is a bridge circuit, on whose Bridge zero branch the display device (18) is switched on. 5. Visibility meter according to claim 4, d a d u r c h g e k e n n shows that there is someone in the bridge's zero branch that reacts to the external light third photosensor (28) is located. 6. Visibility measuring device according to one of claims 1 to 5, d a d u r c h g e k e n n n z e i c h n e t that on that photosensor (11, 21, 25), the the straightening device (10) is connected upstream and the light transmitter (19) acts. 7. Visibility meter according to claim 3, d a d u r c h g e k e n n notices that each photo sensor is preceded by a straightening device.