DE19635279A1 - Light (IR) and HF signal transmission method esp. for light and HF signals in vehicle anti-theft device - Google Patents

Abstract

The transceiver method uses an alert signal (WS) in the HF range provided before transmission of the useful HF signals (HF1,HF2), with at least partial interlacing of the alert signal with the light signals (IR). The receiver is held in a standby mode with a reduced current consumption until reception of the alert signal, causing it to switch to the reception mode, for reliable reception of the useful HF signals. Pref. the method uses a first receiver for receiving light signals (IR) and a second receiver to receive the HF signals (WS, HF1, HF2) during a specified receiving period. The second receiver is pref. disconnected during the receiving period if no alert signal is received and connected again, when an alert signal is received.

Description

The invention relates to a method for transmitting light and high-frequency signals according to the preamble of the claim 1 and a method for receiving light and Hochfre sequence signals according to the preamble of claim 4.

Appropriate processes are, for example, in the area of Automotive technology used to remote-controlled actuators the, in particular safety devices of the motor vehicle head for

DE 43 00 600 A1 describes a remote-controlled fuse direction known for motor vehicles, the first transmitter for a radio frequency signal, a second transmitter for a Light signal, a first receiver for the radio frequency si gnal and a second receiver for the light signal points. To avoid delays, the transmitters and Receiver switched on at the same time so that the transmitter transmit simultaneously and both the radio and the infra red transmission path can build.

The object of the invention is to ensure that the radio frequency receiver is switched on in time and electricity is saved when operating the receiver. The The object of the invention is defined by the features of claim 1 and 4 solved.

It is particularly advantageous to use wake-up signals in the high frequency range rich before the high frequency signals with useful formation the, and at least partially simultaneously with light signals to send the alarm signals.  

Advantageous further developments and improvements of the invention are specified in the subclaims.

The invention is explained in more detail below with reference to the figures purifies: show it

Fig. 1 A transmitting and receiving unit,

Fig. 2 shows a telegram structure of the light and Hochfrequenzsi gnals, and

Fig. 3 shows a program flow for the reception process.

Fig. 1 shows a transmission unit 1 having a first transmitter 2 and a second transmitter 3. The first transmitter 2 is designed to emit light signals, in particular infrared light. The second transmitter 3 is for emitting high frequency signals, in particular radio frequency signals, out. The light signals and the high-frequency signals are encoded according to different codes, the light signal being encoded before and preferably emitted according to the Quattro phase code and the Hochfrequenzsi signal according to the biphase code.

The transmitter unit 1 has a button 12 for the first transmitter 2 and the second transmitter 3 , by means of which the first transmitter 2 and the second transmitter 3 are activated for transmission. In addition, a voltage supply for the first transmitter 2 and the second sensor of 3 is provided in the transmitter unit 1 . A preferred embodiment of the transmission unit 1 is to accommodate the transmitting unit 1 in a handle of a vehicle key.

1 also are in Fig., A first receiver 4, which is adapted to receive light signals of the first transmitter 2, and a second receiver 5, the ignalen for receiving radio frequency signals, in particular radio Frequenzs, the second transmitter 3 is formed. The first receiver 4 and the second receiver 5 are connected via a first signal line 6 or a second signal line 7 to an evaluation and control unit 8 , which has control lines 9 , which have actuators, in particular locking and unlocking means 10 and / or one Anti-theft device 11 such as an immobilizer are connected.

In Fig. 1, the light signals that are emitted by the first transmitter 2 are in the form of dashed arrows Darge, since light signals propagate linearly and receiving a light signal by the first receiver 4 is not possible if between the first transmitter 2 and the first receiver 4 is a larger object.

The high-frequency signals emitted by the second transmitter 3 propagate in the form of spherical waves which are scattered and reflected on objects, so that control of the second receiver 5 is also possible if there is a between the second transmitter 3 and the second receiver 5 Object is found.

The first receiver 4 and the second receiver 5 convert the received light signal or the received high-frequency signal into a corresponding, preferably electrical or optical first or second signal and conduct this to the evaluation and control unit 8 , which of the most signal lines 6 and the second signal lines 7 evaluates to run first and second signals for the corresponding code and according to the information obtained from the evaluation of the electrical signals via the on control lines 9 corresponding actuating elements, in particular locking and unlocking means 10 and Diebstahlsicherungsein directions 11 drives.

Fig. 2 shows schematically the sequence of the method according to the invention, in which both a light signal and a high frequency signal are transmitted for the transmission of information, the high frequency signal and the light signal are transmitted successively in time and first the light signal IR from the time T0 to the time T1 is sent.

Between the time T0 and the time T2, wake-up signals are emitted in the form of a high-frequency signal, which the evaluation and control unit 8 recognizes on the basis of the predetermined information content, and then changes from an idle state to a normal state in which the evaluation and control unit 8 evaluates the signals of the second receiver 5 . In the idle state, the evaluation and control unit 8 does not evaluate the signals of the second receiver 5 .

In addition, the evaluation and control unit 8 switches the second receiver 5 from a quiescent state in which the second receiver 5 does not receive any signals to a normal state in which the second receiver 5 receives signals after detection of a wake-up signal. In the normal state, however, the second receiver 5 consumes more current than in the idle state.

The wake-up signals ensure that the first high-frequency telegram HF1 transmitted with useful information from time T2 and the second high-frequency telegram HF2 with useful information subsequently transmitted from time T4 are received by second receiver 5 and by the evaluation and control unit 8 can be evaluated.

A wake-up signal and a high-frequency telegram differ in the content that is transmitted. A wake-up signal only contains the information that a high-frequency telegram with useful information follows. For this purpose, the wake-up signal transmits the predetermined bit sequence 101 , for example, so that the evaluation and control unit 8, after evaluating the bit sequence 101, knows that this represents a wake-up signal and a high-frequency telegram follows.

The high-frequency telegram contains useful information that specifies, for example, which security codes a vehicle key has, or whether an immobilizer should be switched on or off. A predetermined synchronization pulse sequence, which is known to the evaluation and control unit 8 and to which the evaluation and control unit 8 is synchronized, is preferably sent at the start of the high-frequency telegram.

In Fig. 2a, the light signal IR, in particular Infrarotsi signal is shown, which is sent from T0 to T1 by the first transmitter 2 . In Fig. 2b, the wake-up signals WS are shown, which are sent from the second transmitter 3 in the period from T0 to T2. Subsequently, the second transmitter 3 transmits the first high-frequency telegram from time T2 and after a transmission pause, as shown in FIG. 2b .

Preferably, the same information is transmitted in the first and second high-frequency telegram, so that the evaluation and control unit 8 can check the evaluation of the first high-frequency telegram for errors using the second high-frequency telegram.

For a particularly low power consumption, the second receiver 5 is supplied with power by the evaluation and control unit 8 only at given time intervals, in this exemplary embodiment every 150 ms for a predeterminable reception period and switched to reception. If no wake-up signal is received during the reception period, the evaluation and control unit 8 switches the second receiver 5 off again.

In order to ensure that the first high-frequency telegram HF1 is received by the second receiver 5 , the second receiver 5 must be switched to receive at the latest at the time T2 = 150 ms after the transmission unit 1 has been actuated. If the second receiver 5 is not active at the time T2, the first high-frequency telegram HF1 is not completely received, so that the second high-frequency telegram HF2 cannot be used for error control.

Advantageously, the sending of the wake-up signals ensures that the second receiver 5 receives a wake-up signal during the reception period and is switched into a reception state by the wake-up signal. The time interval between two wake-up signals is advantageously shorter than the reception period, so that it is ensured that when the wake-up signals are sent, the second receiver receives a wake-up signal for at least 5 minutes, so that it is ensured that before the transmission of the first high-frequency telegram HF1 the evaluation and control unit 8 switches the second receiver 5 to reception in good time.

The wake-up signals in the high-frequency range and the light signal HF, IR are preferably sent simultaneously, as shown in FIG. 2c, so that both a light signal and a wake-up signal WS are sent within a time window of preferably 2 ms. In one development, the light signal and the wake-up signal WS are emitted simultaneously.

In this way, the time from T0 to T1 during which the Light signal is transmitted, also for the transmission of Wake-up signals are used, causing a shortening of the total Send time for the transmission of the alarm signals and the Hochfre frequency signals with useful information is reached.

Fig. 3 shows a program flow for carrying out the reception process. At program point 20 , the evaluation and control unit 8 switches the second receiver 5 to receive for a prescribable reception period of preferably 4 ms and evaluates the signals supplied by the second receiver 5 in the reception period. After the reception period has elapsed, the evaluation and control unit 8 checks at program point 21 whether a wake-up signal in the high-frequency range has been received by the second receiver 5 and reported to the evaluation and control unit 8 .

If this is not the case, a branch is made to program point 22 , in which the evaluation and control unit 8 switches off the second receiver 5 and itself goes into the idle state. After a predefinable waiting time, preferably 15 ms, the program branches to program point 20 .

If, however, it is determined at program point 21 that a wake-up signal has been received, then at the following program point 23 the second receiver 5 is kept on reception by the evaluation and control unit 8 for a predeterminable period of time and the signals supplied by the second receiver 5 are received by the evaluator - And control unit 8 evaluated so that the first and second high-frequency telegrams HF1, HF2 are received safely.

After receiving the first and the second high-frequency telegram, the evaluation and control unit 8 switches off the second receiver 5 at program point 24 and the signals supplied by the second receiver 5 in the subsequent period are no longer evaluated. The program then branches to program item 22 .

With the described method, both the broadcast time for the transmission of the light signal and the high-frequency signal les and the reception time in which the second receiver is on Reception is switched, shortened. Security also increased for receiving the high-frequency telegrams HF1, HF2.

Claims (6)

1. A method for sending light signals (IR) and Hochfre frequency signals, which are sent in a predetermined time sequence, characterized in that first wake-up signals (WS) in the high frequency range before the high frequency signals (HF1, HF2) are sent with useful information, and that Wake-up signals (WS) are sent at least partially simultaneously with the light signals (IR). 2. The method according to claim 1, characterized in that in a time window first for a predetermined period of time Light signal (IR) and then for a predetermined time duration a wake-up signal (WS) is sent. 3. The method according to claim 1, characterized in that after the sending of the light signal (IR) further wake-up signals (WS) be sent until the radio frequency signal (HF1, HF2) with Payload is sent. 4. A method for receiving light and Hochfrequenzsigna len, characterized in that a first receiver ( 4 ) for the light signal (IR) is switched to receive that a second receiver ( 5 ) for the high frequency signal (WS, HF1, HF2) is switched to reception at predetermined time intervals for a given reception period, that the second receiver ( 5 ) is switched off after the reception period if no wake-up signal (WS) is received, that the second receiver ( 5 ) remains switched to reception if during a wake-up signal (WS) is received during the reception period. 5. The method according to claim 4, characterized in that the second receiver ( 5 ) after receiving a wake-up signal (WS) remains switched to reception for a predeterminable period of time, and that after the predeterminable period of time the second receiver is switched off if no further Wake-up signal (WS) or high-frequency signal (HF1, HF2) is received during the predefinable period. 6. The method according to claim 4, characterized in that a Light signal (IR) and a wake-up signal (WS) at the same time, ins particularly within a predeterminable time window be.