DE3803920A1 - Decoder for remote controls - Google Patents

Abstract

A decoder (4) for remote controls with serial transmission, which allocates particular transmitter commands to in each case particular decoder outputs (7) for particular subscribers or subscriber functions. According to the invention, it is provided that the allocation can be programmed in the decoder (4) and that the latter is set up for learning information words from a predetermined transmission format and for then recognising them again. <IMAGE>

Description

The invention relates to a decoder for remote control with serial transmission, the specific transmitter commands certain decoder outputs for certain participants or subscriber functions, for example consumers or Assigns consumer functions. Decoders ensure that Control commands from a transmitter are checked whether the Sender or the respective control command is permitted and the Implement commands in this way and forward them to a decoder output ten that a connected consumer or certain Consumer functions can be controlled.

Such decoders are in a wide variety of designs men on the market. Here certain outputs are circuit technically assigned to specific transmitter signals.

The invention has for its object a decoder for To develop remote controls, the greater flexibility in loading drive use enables.

The task described is solved according to the inven tion in that the assignment is programmable in the decoder and that he is set up to use information words to learn a given transmission format and there after recognizing. Through programming, one can certain transmitter signal a certain decoder output can be assigned and the decoder is based on this signal set that one after the intended assignment of a Output receives the transmitter signal to be assigned, whereby the decoder sets this up for the particular output.

The decoder can be constructed so that a microcomputer  with a non-volatile memory and display for the Programming state works together. This allows the Monitor the programming process clearly. The display can also be designed so that the operation of each because the control command is displayed.

The microcomputer can by program or by a fixed put circuit to be set up advantageously that it has fewer control buttons for assignment than Decoder outputs are available, is programmable. Thereby it becomes particularly easy to use.

After further training, the decoder is set up so that in addition to assignment by programming, functions of the Signal word are programmable within an assignment. This allows a signal from the transmitter to perform a specific function trip can be assigned. So a certain exit the function trigger for a certain consumer stale assigned to keys or keys. When switching, this causes Signal a permanent change in the switching state during when switching, the switching status is only changed as long as the signal is present.

The decoder requires only a few buttons, if the functions are also controlled by the control buttons for the assignment are programmable.

The invention is now based on in the drawing roughly cal illustrated exemplary embodiments in more detail be tert :.

In Fig. 1, the structure and cooperation of the decoder is illustrated in the manner of a block circuit diagram.

In FIG. 2, an embodiment is shown for programming.

In the example according to FIG. 1, a microcomputer 1 , a non-volatile memory 2 and a programming display 3 together with control buttons T 1 and T 2 form the essential components of the decoder 4 . A sensor 5 of the decoder 4 can receive signals from a sensor 6 , for example infrared or ultrasound signals and converted into electrical signals and supply the microcomputer 1 . At outputs 7 , in the order 71 , 72 to 7 n , loads 8 or consumer functions within a consumer can be connected and controlled.

The decoder 4 can be programmed by the control buttons T 1 , T 2 , so that a certain signal of the transmitter 6, a certain output 7 , one of 71 to 7 n , is assigned. The decoder is set up to learn a predetermined and transmitted signal for an assigned output within the framework of a transmission format seen before and to recognize it from the storage. Here, the operation for programming is simplified if fewer control buttons are provided than the decoder has outputs 7 . For example, the outputs 71 to 7 n can be acted upon by the control buttons T 1 and T 2 .

Programming with two control buttons T 1 and T 2 will be explained in an exemplary manner with reference to FIG. 2. The program 9 , in order to assign a specific transmitter signal and a specific operating function to a specific output, begins, for example, by simultaneously pressing the control buttons T 1 and T 2 , the program step 10 , which can be understood as the opening mode. In a next program step 11 one of the keys, for example the key T 1 , is pressed as often as the order number 1 to n of the assigned output terminal, for example corresponds to the output 73 with the order number 3 . In this case, press the T 1 button three times. In the next program step 12 , the transmitter signal to be assigned is emitted, that is to say, for example, the corresponding transmitter key is pressed. In the next program, step 13 , it is checked whether corrections KR are necessary, ie whether the assignment of the transmitter signal to the decoder output is the desired one. If this is not the case, i.e. a correction is required, another transmitter button can be pressed. Otherwise, the program step 14 can follow. Any necessary correction can be optically recognized by the operator, for example, if the programming display 3 is set up accordingly, as will be explained further below. In a program step 14 , the decision can be taken into account whether the control button T 2 should be pressed in a program step 15 , for example to define the switch function, or in a program step 16 by pressing the control button T 1 the function button should be defined as the mode of operation. In a subsequent program step 17 , test program TE, the program can be tested by checking whether the intended output of the decoder and the desired function have been assigned to a given transmitter signal to be assigned. In a program step 18 , in a loop to the program step 10 further assignments for outputs of the decoder can follow or the end 19 of the programming, after which the decoder is ready for the assigned outputs.

In the exemplary embodiment according to FIG. 2, a certain function is also assigned to the signal word in program steps 14 to 16 . Within the "switching" function of a consumer 8 , the function or mode of operation for a signal word is also assigned, that is to say "switch" or "button". Here, these functions and modes of operation are also programmed by the control buttons T 1 , T 2 , which on the other hand also assign a specific output of the decoder to a specific transmitter signal.

The programming display 3 can be designed as follows:

If the programming display performs with an LED out is the program step 11, a sequence of flashing signs with intermediate prolonged blackouts abge give that matches the serial number of the decoder output. If the programming display is designed with segments for representing digits, for example as a 7-segment display, the order number of the decoder output to be assigned can be displayed. In program step 12 , where a transmission telegram ST is assigned, this can light up for a programming display with an LED as long as the transmission telegram is received to indicate that the transmission telegram is recognized. When designed as a segment display, the order number can light up as long as the send signal is received. In programming step 15 or 16 , the order number for a light-emitting diode can, for example, flash every second, for example for the order number three flashes three times every second. When running as a segment display, the order number added to the output of the decoder can flash every second or a special character can be briefly output. In program step 17 , the test TE, the version with the LED can light up as long as the transmitter telegram or the transmit words are received. Accordingly, the number of the output can light up for a segment display. After completion of the program, that is to say in the operational state of the decoder after the end of programming 19 , the programming display 3 can light up as long as a transmission telegram to be evaluated is received. In the case of a version with a segment display, the ordinal number can light up accordingly during transmission reception.

The programming described and the execution of the decoder are only to be understood as exemplary embodiments that the ever due to modifi can be decorated.

Claims (5)

1. Decoder ( 4 ) for remote controls with serial transmission, which assigns certain transmitter commands to specific decoder outputs ( 7 ) for certain subscribers or subscriber functions, for example consumers or consumer functions, characterized in that the assignment is programmable in the decoder ( 4 ) and that it is set up to learn information words from a predetermined transmission format and then to recognize them again. 2. Decoder according to claim 1, characterized in that a microcomputer ( 1 ) cooperates with a non-volatile memory ( 2 ) and a display ( 3 ) for the programming state. 3. Decoder according to claim 1, characterized in that a microcomputer ( 1 ) by fewer control buttons ( T 1 , T 2 ) are available as decoder outputs, is programmable. 4. Decoder according to claim 1, characterized records that in addition to the assignment by programming tion, also functions of the signal word within a door order are programmable. 5. Decoder according to claim 4, characterized in that the functions are programmable by the control buttons (T 1 , T 2 ) for the assignment.