DE3803541A1 - Receiver unit, for example for a motor vehicle - Google Patents

Abstract

The invention relates to a light-controlled receiver unit for remotely controlling the control unit (SE) of a part of a system, for example for remotely controlling the door-lock control relay (SE) of a motor vehicle, by means of an optical receiver element (E2), for example a photodiode (E2), which controls an electronic receiver (W) which contains one or more amplifier elements, two optical receiver elements (E1, E2) being fitted to the system, of which receiver elements the first receiver element (E1) is connected in an optically (S, IR) controllable manner and via an electronic amplifier (V) to an optical transmitter element (D) which (D), for its part, can optically (L) re-emit the signals (IR) received by the first receiver element (E1) and the second receiver element (E2) optically receives the signals (L) transmitted by the transmitter element (D) and feeds them to the receiver (W). <IMAGE>

Description

The invention improves that in the preamble of claim ches 1 defined receiving unit, which be several times for itself is known.

It turned out that there are a number of cases in which - e.g. B. for reasons of space or design - the optical emp Catch element actually at a greater distance from the recipient would have to be attached, perhaps also because between the Receiving element and the recipient one or more opaque visible body, namely z. B. the padding on the Inner wall of the motor vehicle is located. In this case, but longer electrical lines between the receiving element and inserted into the receiver, such lines then are susceptible to interference and / or have too large attenuations reliable operation of the receiving unit even in the event of malfunctions through - e.g. B. electromagnetic, inductive or capacitive coupled - to ensure environmental influences. Even an ab Shielding these cables is often not sufficient. Except it can even happen that your own strong preliminary more directly at the receiving diode, which the on the Verify lines to be transmitted signals beforehand strengthens, in many cases - e.g. B. again for reasons of space or Design reasons - not to be attached to the receiving element can.

Such long lines between the are particularly uncomfortable Receiving element and the recipient even if the recipient is a very complex, complex unit, which - e.g. B. for reasons of cost or space - in the system only one only time - e.g. B. centrally in the system - to be installed,  and if here several different optical receiving elements, to be attached to the system at large distances are, e.g. B. to the system part from different directions to be able to control remotely.

The invention avoids those long lines between the emp catch element and the receiver by the in claim 1 specified measures.

The additional measures specified in the subclaims allow additional advantages to be achieved. Among other things, the measures according to
Claim 2 to mount a single common receiver for a plurality of spatially distributed first receiving elements,
Claim 3 to attach several, independently working first receiving elements,
Claim 4 to install several intermediate units forming a derailleur circuit,
Claim 5 to increase security against unauthorized or unintentional actuation of the system organ,
Claim 6 to overcome opaque walls lying in the light path,
Claim 7 to control car door locks and
Claim 8 to control garage doors.

The invention and its developments are based on the in the Figures shown examples explained further. Here shows the

Fig. 1 is a schematic diagram of an infrared light-controlled example of the receiving unit and

Fig. 2 shows an example of the receiving unit, which is attached in the front part of a car roof.

Both figures thus show examples of a receiving unit with a key-like transmitting part S emitting the infrared light IR , the light beam IR of which controls the first optical receiving element E 1 . This receiving elements E 1 can, for. B. a phototransistor or a photodiode, which may have been made by additional means such as filters and the like, particularly sensitive to the light beam IR corresponding Lichtwel lenlänge.

At this optically controlled first receiving element E 1 , the amplifier V is electrically connected, which amplifies the electrical output signals of the receiving element E 1 so that an optical transmitter element D attached to the amplifier output in turn, controlled by the transmitter part S , emits optical signals L. In Fig. 2 it is indicated that a short line M can be attached between the amplifier V and the transmission element D. This line M should ever - if it is attached at all - be so short that the operation of the entire receiving unit remains reliable even with inductive, capacitive and / or electromagnetic interference.

Both figures additionally show the second optical receiving element E 2 , which, for. B. can again be formed by a photodiode or by a phototransistor. Emp to this second catch element E 2 of the electronic receiver W is connected, which may contain one or more enhancer elements and, see FIG. Fig. 1, in the example shown in the two figures In addition play a decoding unit Dec as well as possibly even a comparator unit for comparing the decoded signal with a reference code contains. The second receiving element E 2 thus receives the optical signals L emitted by the transmitting element D and, controlled by these optical signals L and thus controlled by the transmitting part S , forwards these signals to the receiver W as electrical signals. At the output of the Emp catcher W , the control unit SE shown only in FIG. 1 is closed, which, for. B. by the control relay SE of door locks of the car shown in Fig. 2 can be formed.

Both figures therefore show examples in which long electrical lines between the first receiving element E 1 on the periphery of the system - that is, on the periphery of the car - to the relatively distant receiver W are avoided. Referring to FIG. 2, the receiver is W z. B. in the roof B / H of the car between the roof panel B and the interior padding H. This avoidance of that long line is particularly demonstrated by the example shown in FIG. 2, in which the first element E 1 receiving element is mounted directly behind the windscreen F of the car on the outside of the roof panel B or the upholstery H , the transmitting element D optically Forwarding signals L to the second receiving element E 2 attached to the receiver W.

Fig. 2 also demonstrates another advantage of the inven tion. Although the second receiving element E 2 together with the receiver W - z. B. for space and / or design reasons - was installed inside the roof padding H or in an air gap between the roof padding H and the roof panel B of the car, and although the padding H at the front of the roof B / H prevents the light from shining IR can be received directly by the second receiving element e 2 with reliably sufficient light intensity can be obtained by the invention, the receiver W by the far ent fernte first receiving element e 1, despite the avoidance of a long electric wire, are controlled by means of the transmitting part S - even if , e.g. B. for space or design reasons, a large distance between the first receiving element E 1 and the receiver W is unavoidable and / or even if an inevitably absolutely opaque wall between the transmitting part S and the receiver W is inevitable.

The invention allows, cf. Fig. 2, the second element E 2 receiving element other than shown in Fig. 2 in the car NEN, so it z. B. by a second receiving element E 2 ' to set, which can be attached in an air gap between the roof panel B and the padding H. The transmitting element D can then send its light L ' also in this air gap between the roof panel B and the padding H to the second receiving element E 2 , controlled by the transmitting part S. In this case, the transmitting element D therefore no longer needs to be close to the inner surface of the padding H , cf. Fig. 2 to be attached, but it can also be attached directly, together with the amplifier V , in the air gap between the roof panel B and the padding H.

In the system in question, e.g. B. in the car shown in Fig. 2, although only a single common receiver W , but at the same time also several, spatially distributed around the system surface first receiving elements E 1 , each with its own amplifiers V and each with its own transmitting elements D is introduced be to the relevant control unit SE of the system in part - so z. B. the door lock relay SE - to be able to optically control spatially from different directions from afar by means of the control part S , without having to install long electrical lines between the first receiving elements E 1 and the receiver W. Here, each form a first receiving element E 1, a thereto belonging amplifier V and an associated transmitting element D together rule unit own Zvi E 1 / V / D, wherein a plurality of such intermediate units E 1 / V / D may be spread around the receiver W and each of these transmission elements D of these intermediate units can independently transmit light beams L or L ' to the second receiving element E 2 of the receiver. This variant of the invention is particularly advantageous if the receiver W is a complicated, very complex unit, which - for. B. for cost reasons - if possible, should only be brought once within the system.

If there are several opaque walls one behind the other between the transmitter part S and the receiver W , several intermediate units E 1 / V / D can also be inserted one behind the other in chain between the sensor part S and the receiver W. The individual inter mediate units E 1 / V / D then form the links of a chain circuit and are then individually one after the other in the walls z. B. attachable so that in the direction of the transmitting part S each Weil a first receiving element E 1 and in the direction of the receiver ger W each of the associated transmitting element D is.

Incidentally, a more or less long fiber optic light path can be inserted entirely or partially along one or more of the light paths of the light beams IR and / or L or L ' , thereby causing the relevant light beam IR or L or L' there can also be directed around corners. This often simplifies the attachment of the intermediate unit E 1 / V / D.

In the examples shown in the figures, the receiver W not only contains one or more amplifier elements, but additionally also the comparator unit and the already mentioned decoding unit Dec which decodes the signals IR, L received via the receiving elements E 1 , E 2 . If the transmitting part S emits a coded signal IR , the decoding unit Dec and the comparator unit checks whether the code emitted by the transmitting part S corresponds to the target code or not, cf. e.g. B. the method described in DE-PS 29 06 665. Then, when the decoded signal corresponds to the target code, the receiver W sends a control command A to the control unit SE for actuating the relevant system part - that is, for. B. for actuating the control relay of one or more of the door locks of the car. Then, however, if the decoding unit Dec and the comparator unit determine that the decoded signals do not correspond to the target code, the receiver W does not issue a control command A to the relevant control unit SE . In this way, a high level of security against unauthorized or unintentional actuation of the relevant control unit SE is achieved.

As already explained in connection with FIG. 2, the invention is also suitable for overcoming opaque walls lying in the light path if the control unit S is to optically control a receiver W and thus a control unit SE inside the system. For this purpose, the first receiving element E 1 together with the amplifier V and the transmitting element D in the opaque wall, cf. e.g. B. B / H in Fig. 2, that the first receiving element E 1 more or less close to the outer wall side of the system, see. B in Fig. 2, and the transmitting element D more or less close to the other wall side of this wall, cf. H in Fig. 2, attached.

The fact that the system in question is a car, cf. Fig. 2, and that the control unit SE controls the locking of at least egg ner of the doors of the car, the achievement is particularly suitable for controlling the door locks of this car.

However, the invention is not limited to this. The fact that the system z. B. is a garage and that the control unit SE z. B. controls the gate of this garage, namely, the invention also allows him to control the garage door in question. Here, the first receiving element E 1 z. B. attached to the outer wall of the Ga rage. The system controlled by the control unit SE then provides z. B. represents an electric motor that moves the garage door.

Claims (9)

1. Light-controlled (S, IR, L) receiving unit for remote control of the control unit (SE) of a system part, for. B. for remote control of the door lock control relay (SE) of a motor vehicle with

• - An optical receiving element (E 2 ), for. B. a photodiode (E 2 ), which controls an electronic, one or more Ver containing amplifying elements receiver (W) ,

characterized in that

• - On the system (F, B, H) two optical receiving elements (E 1 , E 2 ) are attached, of which
  • - The first receiving element (E 1 ) is optically controllable (S, IR) and is connected via an electronic amplifier (V) to an optical transmission element (D) , which (D) in turn is received by the first receiving element (E 1 ) Si gnale (IR) can radiate optically (L) again, and
  • - The second receiving element (E 2 ) optically receives the signals (L) emitted by the transmitting element (D) and feeds the receiver (W) .

2. Receiver unit according to claim 1, characterized in that

• - Several first receiver elements (E 1 ) are each connected to their own intermediate units (E 1 / V / D) via their own amplifiers (V) , each with its own transmitter element (D) .

3. Receiver unit according to claim 2, characterized in that

• - The transmitting elements (D) of at least some of the various intermediate units (E 1 / V / D) can independently send their light beams (L, L ') to the second receiving element (E 2 ).

4. Receiver unit according to claim 2 or 3, characterized in that

• - The transmitting elements (D) of at least some of the various NEN intermediate units (E 1 / V / D) can only send their light beams (L, L ') to the second receiving element ( E 2 ) depending on the other that the transmitting element (D) one interim rule unit (e 1 / V / D) first of such other sends its light beams (L, L ') to the first receiving element (e 1) intermediate unit (e 1 / V / D) before their transmission element (D) his Beam of light (L, L ') forwards to the second receiving element (E 2 ) (chain connection of the intermediate units).

5. Receiving unit according to one of the preceding claims, characterized in that

• - The receiver (W) contains a decoding unit (Dec) for decoding signals (IR) received via the first receiving element (E 1 ), and
• - The decoding unit (Dec) then, if the decoded signals correspond to a target code, issues a control command (A) to a control unit (SE) for actuating the system part, but then if the decoded signals do not correspond to the target code , does not give the control command (A) to the control unit (SE) .

6. Receiving unit according to one of the preceding claims, characterized in that

• - The first receiving element (E 1 ) together with the amplifier (V) and the transmitting element (D) are so mounted in an opaque wall (B, H) that the receiving element (E 1 ) and more or less close to one wall side the transmitting element (S) is more or less close to the other wall side.

7. Receiver unit according to one of the preceding claims, characterized in that

• - the system is a car and
• - The control unit (SE) controls the locking of at least one of the doors of the car.

8. Receiver unit according to one of the claims 1 to 6, characterized in that

• - the system is a garage and
• - The control unit (SE) controls the garage door.