DE3607762C2 - Automatic remote control device - Google Patents

Description

The invention relates to an automatic remote control device the genus of the main claim.

The known remote control devices for data and voice have the Disadvantage of using a complicated and expensive construction specially developed units.

DE 34 12 508 A1 describes a device for radio transmission of Voice and data known by simple switching use as sender and receiver for data and voice lets, data and language without separate conversion of Facility to be transferred. Furthermore, it is from the US-PS 4,461,013 known, an FM transmitter for voice and data to create, whereby data is transmitted when a Keyboard is pressed. If no keyboard is pressed, it is Voice transmission possible. From US-PS 4,521,891 finally known a multi-channel data transmission system by means of which it is possible to connect several to one broadband cable Connect communication channels to thereby the Increase transmission capacity. The individual terminals are connected to the broadband cable via modems.

Based on this state of the art, it is the task of Invention to an automatic remote control device create that independently on a second wire line Can recognize data signals and the corresponding channels of the Remote control device unlocked.

This object is solved by the features of the main claim.

The automatic remote control device according to the invention with the kenn Distinguishing features of the main claim has the advantage that an un disrupted and secure data and voice transmission over a two-wire line is possible and that for the remote control device essentially only Components that are often used in transmission technology are used.

The measures listed in the subclaims are advantageous Developments and improvements to the Fern specified in the main claim control device possible. An invention is particularly advantageous according remote control device in which between the first modem and the Matching circuit another switch is provided, which is in the idle state is closed and open when a squelch signal is present and after Recognize the code sequence is closed again. So the advantage is ver bound that when receiving data the NF signals from the radio transmission and -Receiver does not have the first branch until the code sequence is recognized can get to the first modem. This would be the first modem the presence of signals on the two-wire line can be simulated.  

Exemplary embodiments of the invention are shown in the drawing using several Figures shown and explained in more detail in the following description. The drawing shows in

Fig. 1 is a block diagram of an automatic remote control device according to the invention,

Fig. 2 is an expanded block diagram of a first and second modems and a Datenfernauswerteeinheit the automatic remote control device according to Fig. 1,

Fig. 3 is a block diagram of an evaluation logic unit,

Fig. 4 shows a data signal from a data telegram with a switch code and

Fig. 5 is a block diagram of a remote control device in an alternative to Fig. 1 embodiment.

In FIG. 1, FE denotes a remote control device which is assigned to a local radio transmission and reception station SE with a transmission and reception antenna AN. The remote control device FE is connected to the local radio transmitter and receiver station SE, preferably post own two-wire line ZL and has two connections A1 and A2, of which the first connector A1 with the local radio transmitter and receiver station SE and the second connector A2 is preferably connected to a control center, which is omitted in FIG. 1 for the sake of clarity.

Between the connections A1 and A2 there are two parallel branches Z1 and Z2, an adapter circuit AP being provided between the second connection A2 and the two branches Z1 and Z2. Seen from the adapter circuit AP, the first branch Z1 contains a series connection of a remote control unit FBE and a switch SCH and the second branch Z2 a series connection of a first modem M1, which is a data modem approved by the postal authority, a remote data evaluation unit DFE and a second modem M2, this is a radio modem. The modems M1 and M2 each have a modulator M, a demodulator D and an interface S1, S2, which is preferably a V24 interface, which corresponds to an interface S3, S4 of the remote data evaluation unit DFE. The switch SCH is controlled by the remote data evaluation unit DFE via the second modem M2 - cf. dashed line in Fig. 1 - and is closed in the idle state.

The operation of the automatic remote control described above device FE is as follows.

The two-wire line ZL should be used for data or voice in both directions signals are transmitted. Are, for example, at the second connection A2 Speech signals, they arrive via the adapter circuit AP, the elek trical adaptation of the two-wire line ZL (postal line) to the branches Z1 and Z2 takes over the remote control unit FBE and the closed Switch SCH to the radio transmission and reception station SE through the remote operating unit FBE is keyed up so that the voice signals over the Transmitting and receiving antenna AN are sent out. In the second branch Z2 hit the speech signals on the demodulator D of the first modem M1. The demodulated signals are transmitted via the interfaces S1 and S3 of the data remote evaluation unit DFE supplied, which does not respond to voice signals.

Meet at the second connection A2 low-frequency, preferably frequency keyed data signals, so would the remote control unit FBE also respond to these signals. Forwarding the data signals via the remote control unit FBE to the transmitter of the radio transmission and -Receiving station SE, however, prevents the switch SCH then opened is operated by the remote data evaluation unit DFE as follows. The on the second terminal A2 data signals are in the demodulator D of the first modem M1 demodulated and processed. Via the interfaces S1 and S3 receive the processed data signals to the remote data evaluation unit DFE.  

This determines whether the data being transmitted is data from the existing transmission system or data signals which happen to be contained in the voice signal. If the remote data evaluation unit DFE unequivocally determined that data is present, then it causes the switch SCH to be opened via the connection shown in dashed lines in FIG. 1, so that the branch Z1 is switched off and the data signals arriving via the remote control unit FBE have no interference with the first Can cause connection A1. From the remote data evaluation unit DFE, the demodulated data signals arrive via the interfaces S4 and S2 to the modulator M of the second modem M2 and via the first connection A1 to the transmitter S of the radio transmission and reception station SE. The data signals are then emitted via the transmitting and receiving antenna AN.

In an analogous manner with the radio transmission and reception station SE received voice or data signals in the remote control device FE separately via branches Z1 or Z2 and then via the adapter scarf device AP forwarded to the second connection A2.

In FIGS. 2 and 3 modem M1, M2 and modem Datenfernauswerte unit are DFE shown in greater detail. Modems M1 and M2 ( Fig. 2) have the following interface connections: RD (Receive Data), DCD (Data Channel Receive Line Signal Detector), RC (Receiver Signal Element Timing DCE), TC (Transmitter Signal Element Timing DCE), RTS (Request to Send) and TD (Transmit Data). The mentioned connections of the two modems M1 and M2 are connected to one another via lines L1 to L6, namely the connection RD of the first modem M1 with the connection TD of the second modem M2, the connection DCD of the modem M1 with the connection RTS of the modem M2 , The connector RC of the modem M1 with the connector TC of the modem M2, the connector TC of the modem M1 with the connector RC of the modem M2, the connector RTS of the modem M1 with the connector DCD of the modem M2 and the connector TD of the modem M1 connected to the RD port of the M2 modem. The connection designations used above correspond to the standardized designations of V24 interfaces (EIA designation). The second modem M2 has a further connection "AS", which is connected via a line L7 to the output 0 of an evaluation logic AWL.

The lines L1 and L6 are also connected to a first changeover switch U1, the lines L2 and L5 to a second changeover switch U2 and the lines L3 and L4 to a third changeover switch U3. The changeover switches U1 to U3 are combined to form a changeover switch unit U which is controlled via the second line L2. The movable contact of the first switch U1 is connected to a data input D ( FIGS. 2 and 3) of an evaluation logic AWL, the movable contact of the second switch U2 to a reset input R and the movable contact of the third switch U3 to a clock input C. A switching signal at an output 0 of the evaluation logic AWL controls two switches b11 and b12, of which one switch b11 is in line L2 and the other switch b12 is in line L5. Both switches b11, b12 are open in the idle state. In the idle position, the changeover switches U1 to U3 connect the line L6 to the data input D, the line L5 to the reset input R and the line L4 to the clock input C of the evaluation logic AWL. The data input D of the evaluation logic AWL ( FIG. 3) is connected to a first shift register SRI, the outputs of which are connected via an evaluator AW to an input El of a second shift register SR2. Every eighth output of the second shift register SR2 is connected to an AND circuit UD, the output 0 of which simultaneously forms the output of the evaluation logic AWL. The first shift register SRI has a reset input R1, which is connected to the input R of the evaluation logic AWL and a reset input R2 of the second shift register SR2, and a clock input C1, which has the clock input C of the evaluation logic AWL and one first input of a NOR circuit NR is connected. A second input of this NOR circuit is connected to the output 0 of the AND circuit UD and the output of the NOR circuit to a clock input C2 of the second shift register SR2.

According to FIG. 4, a switching code is preceded by a data telegram to be transmitted, which enables the clear distinction between data signals and voice signals. The switching code preferably consists of a sequence of, for example, three identical switching codes 1 A, 1 B, 1 C with a length of 7 bits. The Baker code is preferably suitable as the switching code. The evaluation of a data telegram preceded by the switching code follows as follows.

If low-frequency data signals or voice signals pass through the adapter circuit AP ( FIG. 1) in the second branch Z2 to the demodulator D of the first modem M1, then the modem M1 outputs a logic 1 corresponding to the output DCD (Data Channel Received Line Signal Detector) Signal down; thereby all the switches U1, U2, U3 of the switchover unit U are switched together via the line L2, so that only the first modem M1 is switched to the evaluation logic STL. If the low-frequency signals are data signals, for example FSK (Frequency Shift Keying) signals, they pass from the RD (Receive Data) output of the first modem M1 via the changeover switch U1 to the data input D of the evaluation logic AWL; In addition, the clock then lying at the output RC (Receiver Signal Element Timing DCE) of the first modem is fed via the switch U3 to the clock input C of the evaluation logic STL.

The evaluation logic ( FIG. 3) now recognizes whether the predetermined bit pattern ( FIG. 4) that does not appear in the language is present or not. To this end, lying at the data input D of the logical values Schaltkodes be pushed through 1 A in the shift register SR1. The evaluator AW outputs a pulse S1 of the length of a bit to the input E1 of the shift register SR2 from when the parallel outputs of the shift register SR1 of the Schaltkode 1 A, 1 B or 1 C is output. These switching pulses are inserted by the clock at clock input C2 in the shift register SR2. The outputs 0 , 7 , 14 of SR2 each only have a logic 1 corresponding signal if the switching code configuration shown in FIG. 4 has been recognized. In this case, output 0 will emit a signal corresponding to logic 1, whereby relay B1 will be energized and the evaluation logic AWL will lock itself by returning from output 0 via the NOR circuit to clock input C2. The relay B1 then closes the switches b11 and b12 ( FIG. 2), as a result of which the receiving modem, with its DCD signal, switches on the transmitter of the other modem via its RTS input and the received data RD are forwarded to the input TD of the other modem. If the receiving modem outputs a logic 0 signal after the data signals have not been sent to the DCD output, the evaluation logic is reset and the transmission process is ended.

In an alternative exemplary embodiment to FIG. 1 shown in FIG. 5, a remote control device FE1 has the following structure. In addition to a first switch SCH1, which is located between the remote control unit FBE and the radio transceiver SE, there is a second switch SCH2 between the adapter circuit AP and the first modem M1. The second switch SCH2 is controlled by an OR circuit OD, the first input of which is connected to an output DE of the remote data evaluation unit DFE. This outputs a logic 1 corresponding signal at the output DE when the remote data evaluation unit has recognized the switching code according to FIG. 4, and a logic 0 corresponding signal - data error signal - when the remote data evaluation unit DFE has not recognized the specified switching code. A second input of the OR circuit is connected to a squelch output SQ of the radio transmission and reception station SE. The squelch output SQ emits a logic 0 corresponding signal when the radio transmitting and receiving station receives an RF carrier. If a logic 0 corresponding signal is present at both inputs of the OR circuit OD, the switch SCH2 is opened. Thus, a LF signal received by the receiver E of the radio transmitting and receiving station cannot reach the first modem via the first switch SCH1, the remote control unit FBE and the adapter circuit AP, but only to the connection A2 of the remote control device FE1.

On the other hand, if the data evaluation unit DFE recognizes the switching code sequence, it remains the second switch SCH2 is closed and the first switch SCH1 is ge opens. Should an LF signal - data signal or voice signal - be sent? , the switches SCH1 and SCH2 are initially closed. Then recognize the remote data evaluation unit DFE the switching code, the switch SCH1 opened, and the switch SCH2 remains closed.

Claims (9)

1. Automatic remote control device for switching low-frequency data signals and voice signals which are supplied to the remote control device via a two-wire line and which are emitted by a radio transmitter and receiver station following the remote control device, characterized in that the remote control device (FE) has two parallel branches (Z1, Z2), of which one branch (Z1) contains a switch (SCH) and of which the other branch has a series connection of a first modem (M1), a remote data evaluation unit (DFE) and a second modem (M2), and that the remote data evaluation unit (DFE) contains evaluation logic (STL) which recognizes the transmission of data signals and, in the event of recognition, actuates the switch (SCH) in such a way that the connection of one branch (Z1) to the radio transmission and reception station (SE) is interrupted. 2. Remote control device according to claim 1, characterized in that the parallel branches (Z1, Z2) on that of the radio transmission and reception end (SE) facing away via an adapter circuit (AP) with the Two-wire line (ZL) are connected. 3. Remote control device according to claim 1, characterized in that the modems (M1, M2) with the remote data evaluation unit (DFE) via one each V24 interface (S1 ... S4) are interconnected. 4. Remote control device according to claim 1, 2 or 3, characterized records that between the first modem (M1) and the adapter circuit (AP) a further switch (SCH2) is provided, which is in the idle state is closed and open when a squelch signal is present and after recognizing the code sequence is closed again.   5. Remote control device according to claim 1 or one of the following, characterized in that the first modem (M1) is a post modem and the second modem (M2) is a radio modem. 6. Remote control device according to claim 1 or 2, characterized records that the two-wire line (ZL) is a postal line. 7. Remote control device according to claim 1 or one of the following, characterized in that the data in the form of data telegrams are transmitted, which is preceded by a switching code. 8. Remote control device according to claim 7, characterized in that that the switching code from a sequence of switching codes of the same length and the same content. 9. Remote control device according to claim 7 or 8, characterized indicates that the switching code is a Baker code.