DE19622002A1 - Self-dimming rear-view or external mirror for motor vehicle - Google Patents

Abstract

The system has a first sensor (S1) which detects frontal light and a second sensor (S3) which detects the light reflected at the front of the mirror (M) by reflecting the light incident in the direction of view of the observer. The signals output by the sensors are fed into a control logic arrangement (ECU) which outputs a control signal to an actuator which affects the position of the mirror. At least one fluorescent optical fibre conducts the light reflected from the mirror surface to a housing enclosing the mirror. The second sensor is mounted on the end of the fibre inside the housing.

Description

The invention relates to a self-dimming mirror system according to the The preamble of claims 1 or 7.

In such mirror systems, light reflection and / or the position of a Mirror regulated in this way depending on the external lighting conditions be that the observer the image shown in the mirror as glare-free as possible can capture. A preferred use of such mirror systems is e.g. B. in using it as a rear or outside mirror for motor vehicles.

FIG. 3 shows two views of a self-dimming mirror system that are folded by 90 ° relative to one another, as is used in commercially available systems. The difference between the front light E _F (light from the front, against the preferred direction of view of an observer) and the rear light E _R (light from behind, in the preferred direction of view of an observer) is detected by two optical sensors S 1, S 2. The sensors are mounted along the axis of a bore extending through the mirror surface and the housing surrounding the mirror on the opposite sides of a control circuit ECU. The intensity of the front light E _F incident against the preferred direction of view of the observer on the first sensor S 1 attached to the rear of the mirror and the intensity of the observer in the direction of view of the sensor S 2 incident rear light E _R lying in the channel bore on the front of the control circuit is in the Control circuit detected and evaluated. Due to a pre-stored characteristic curve, the control circuit ECU, depending on the signals from the two sensors S 1, S 2, outputs an output signal to an optical actuator OA connected to the movable mirror, which adjusts the mirror position in accordance with the characteristic curve. The resulting reflection E _{M of} the mirror is an output variable of the system, ie it is not measured and, consequently, is not directly controlled.

Fig. 4 shows a block diagram of the control circuit of such a self-dimming mirror system according to the prior art, which again shows that the front light E _F and the rear light E _R are input variables to be measured and the light E _M reflected on the mirror is an output variable to be controlled .

.. However, the known system of reflecting control shown in Figures 3 and 4 has a number of disadvantages:

• 1. It will be a particularly aesthetic and safety Aspects as a disturbing hole found on the front of the mirror needed.
• 2. A hole is required on the back of the mirror housing.
• 3. There is actually no measurement of that on the mirror surface reflected light instead.
• 4. No regulation of the reflection is possible.
• 5. Nonlinearities and tolerances within the system can only are very difficult to compensate.
• 6. Environmental requirements, e.g. B. Compensate for a temperature drifts can only be fulfilled very imperfectly.
• 7. In order to ensure that the system response is physiological Meets the needs of the viewer / driver, one of the Spectral characteristics of the human eye adapted optical Filters are used.

The object of the present invention is therefore to improve to provide self-dimming mirror systems, each as possible avoid many disadvantages of the prior art.  

According to the invention, self-dimming mirror systems with the Features of independent claims 1 or 7 provided, which in In contrast to the known ones based on reflection control self-dimming mirror systems represent systems for reflection control.

In these systems according to the invention, instead of the backlight E _R measured in the prior art, the mirror light E _M reflected on the front of the mirror is the variable to be measured and controlled.

A first system according to the invention is constructed in such a way that a first sensor detects the front light E _F incident in the preferred direction of view of a viewer and a second sensor detects the light E _M reflected at the front of the mirror by reflecting the back light E _F , whereby of the two sensors depending on the light that is incident on them, signals are output in a control logic that outputs a control signal to an actuator acting on the position of the mirror.

As an alternative or cumulatively to the features of the first system, a second system according to the invention has the feature that it is based on the system equation E _F = E _M = k · E _M '. Here, k is a proportionality factor which essentially characterizes the ratio between the intensity E _M of the light reflected at the front of the mirror and the portion E _M ′ registered by a sensor thereof, and E _F corresponds to the intensity of the front light incident in the direction of view of the observer . Here, the reflection control is carried out so that the intensity of the front light E _{F is} equal to the intensity of the light E _M reflected on the front of the mirror. In this case there is no dazzling of the viewer / driver, since this looks at light of the same intensity from two light sources, namely the "background radiation" (front light) and the image of the mirror. In this second system according to the invention, no complicated formula and / or characteristic curve specification is necessary for the control circuit, because a control system with this system equation always "locks" into the glare-free position.

The advantages and features of the present invention also result from the following claims in conjunction with the drawings; show it:  

Figure 1 shows the schematic structure of a mirror system according to the invention in the view from the front and in cross section.

FIG. 2 shows a block diagram of the control loop used in the mirror system according to the invention according to FIG. 1;

. Fig. 3 shows the structure of a conventional selbstdimmenden mirror system in a representation corresponding to FIG 1; and

Fig. 4 is a block diagram of the control circuit used in the known mirror system according to Fig. 3.

Fig. 1 shows the schematic construction of a preferred embodiment of a selbstdimmenden mirror system of the invention. The mirror M is integrated in a surrounding housing G and the edge of the mirror is surrounded by a fluorescent optical fiber F. The mirror M is mounted in the housing G and its position and / or its reflection can be changed by means of a schematically indicated optical actuator OA. At the back of the mirror, a control logic ECU and two optical sensors S₁ and S₃ are housed inside the housing. The first sensor S 1 detects the incident front light in the direction of view of the observer and, depending on the intensity E _{F of} the front light, gives a signal to the control logic ECU.

The fluorescent optical fiber F encompassing the mirror surface along its circumference collects a portion E _M ′ = k · E _M of the light E _M reflected on the mirror surface by reflection of the rear light incident in the direction of view of the observer and directs this to a sensor housed in the housing interior S₃. The proportionality constant k is a characteristic system constant, which includes quantities such as the solid angle portion of the light reflected by the glass fiber at the front of the mirror, the spatial reflection characteristic of the mirror M and the transmission characteristic of the fiber F.

The sensor S₃ gives a reflected and received light intensity E _M 'corresponding signal in the control logic ECU. This compares the incoming signals from the two sensors S₁ and S₃ and generates a control signal which acts on the optical actuator OA in such a way that the position and / or the reflection of the mirror M is changed until the condition is met that the intensity of the incident front light is equal to the intensity of the light E _M reflected on the mirror surface.

This results in a system equation E _F = E _M = k · E _M 'in this case, where k is the ratio between the light E _M reflected on the mirror surface and its fraction E passed through the fluorescent optical fiber F to the sensor S 3 _M 'indicates. The measures of claims 1 and 7 are therefore used cumulatively.

Fig. 2 shows schematically the control circuit underlies a selbstdimmenden mirror system according to the invention. If the control logic ECU is based on the fact that the front light measured by the first sensor S 1 is in a linear relationship with the mirror light E _M measured by the second sensor S 3, there is a simple system equation of the control circuit which without the complicated characteristic curve of that shown in FIG. 4 Control circuit comes into play, in which the intensities of the front light and the mirror light are compared directly with one another and the reflected mirror light E _M merely represents an output variable of the system.

In order to achieve an adaptation to the spectral sensitivity of the human eye, either a filter system upstream of the second sensor with an absorption characteristic corresponding to the spectral sensitivity of the human eye or a characteristic curve corresponding to the spectral sensitivity of the human eye can be used in a system according to the invention the control logic ECU are taken into account, ie the relationship E _F = E _M = k · E _M ′ no longer applies here. This underlines that the measures of independent claims 1 and 7 can also be used alternatively. However, it is particularly advantageous to use a fluorescent optical fiber in the mirror system according to the invention shown in FIG. 1, which shows a sensitivity maximum in the range of visible green light in order to adapt the sensor characteristic to the spectral characteristic of the human eye.

Furthermore, the system design of the self-dimming according to the invention Mirror system facilitated by the fact that fluorescent optical fibers are used, which have a linear behavior of their absorption and Light guiding properties both via the intensity of the incident light as well as showing their entire length.

With a particularly simple constructive system design is also an optical fiber both for measuring the mirror light and for measuring the Headlights used.

In addition, very good protection against dust and moisture is achieved, when the fiber is firmly glued into the mirror housing and seals it becomes. This enables a completely closed mirror system that, for. B. the manufacture of vehicle exterior mirrors is very simplified.

Furthermore, the EMC risks are reduced, the costs, especially for assembly, reduced and improved the overall quality of the system.

The preferred area of use of the mirror systems according to the invention is the use as exterior and / or rear view mirror in vehicles of all kinds.

Claims (8)

1. Self-dimming mirror system for adapting the position and / or reflection of a mirror relative to an observer as a function of the intensities of the front light incident from the rear of the mirror against a preferred viewing direction of the observer and of the incident on the front of the mirror in the viewing direction of the observer Light, characterized,
that a first sensor (S₁) detects the front light (E _F ),
a second sensor (S₃) which detects light (E _M ) reflected on the front of the mirror (M) by reflecting the light (E _R ) incident in the viewing direction of the observer,
whereby from the two sensors (S₁, S₃) depending on the incident light output signals are given in a control logic (ECU) which gives a control signal to an actuator (OA) acting on the position of the mirror (M). 2. Self-dimming mirror system according to claim 1, characterized in that at least one fluorescent optical fiber (F) guides the reflected light (E _M ) from the mirror surface into a housing (G) surrounding the mirror (M), the second sensor (S₃ ) is attached inside the mirror housing at the end of the optical fiber (s). 3. Self-dimming mirror system according to claim 2, characterized, that the sensitivity maximum of the optical fiber (s) in the spectral range of visible green light. 4. Self-dimming mirror system according to claim 2 or 3, characterized in that the optical (n) fiber (s) is used both for measuring the front light (E _F ) and the reflected light (E _M ). 5. Self-dimming mirror system according to one of claims 2 to 4, characterized, that the optical fiber (s) is sealed in the mirror housing (are). 6. Self-dimming mirror system according to one of claims 2 to 5, characterized, that the optical fibers used have a linear absorption characteristic and / or linear light-guiding characteristics along their entire length point. 7. Self-dimming mirror system for adapting the position of a movable mirror relative to an observer depending on the intensities of the front light incident from the rear of the mirror against a preferred viewing direction of the observer and the light incident on the front of the mirror in the viewing direction of the observer, in particular according to one of the preceding claims, characterized in that the mirror position is controlled by means of a control loop which obeys a system equation E _F = E _M = k · E _M ′, where k is a proportionality constant which is the ratio between the intensity E _{M of} the at the front of the mirror reflected light to the portion thereof registered by a sensor (S₃) E _M ', and E _F corresponds to the intensity of the front light incident in the preferred viewing direction of the observer. 8. Use of a self-dimming mirror system according to one of the previous claims in a land, air, water or underwater bound vehicle.