DE2454463A1 - T.V. control data communication equipment - sends different frequencies withdata given by interval at end of signal - Google Patents

Abstract

The data information is given by the duration of the first signal particularly when used for the telecontrol of television receivers. Other data information can be given by an interval of the time at the end of the duration of the first signal. Data representing analogue quantities is given by a first and/or a second time interval, while data representing digital characters is given by one or several time intervals. The equipment has a transmitter which comprises a switched frequency oscillator and push button switches to select telecontrol functions. The push button switches are set in group switches and channel switches, such that the group switches determine the time intervals and the channel switches the end of a duration.

Description

Transmitters for remote control signals, in particular for an ultrasonic remote control in the case of televisions, addition to patent application P 24 29 065.2 in the main application is a system for the transmission of several pieces of information by means of a remote control signal, in particular for an ultrasonic remote control for televisions, described, in which information is given by the duration of the transmitted signal, and in which a different piece of information while the frequency of the signal always remains the same it is thereby given in which of the predetermined time ranges the end of the time period -lies. In this system, it is possible to use a decoder containing a Receiver only the same by evaluating the duration of the transmitted signal Frequency to detect two pieces of information.

While the one information by the duration of the transmitted Signal is given directly, the other information is derived from it.

directed that it is determined in which of several predetermined The transmitted signal ends.

With a well-known ultrasonic remote control (magazine "Funkschar 1973, Issue 18, pp. 675-77), however, is based on the duration of the transmitted signal only one piece of information gained. The other piece of information is given by the frequency of the transmitted signal is determined. The transmitter for the well-known ultrasonic remote control is therefore because of the different frequencies required Resonance circles relatively complex.

The invention is based on the object for that in the main message system described for the transmission of multiple information to create a transmitter. It is also an object of the invention to achieve the greatest possible integration to allow the circuit of the transmitter, with the number of external connections the integrated circuit, (IC), which lead to the peripheral circuit, if possible is low.

The invention is based on a transmitter for remote control signals, which are generated by a frequency switchable oscillator, and with key switches assigned to the desired remote control functions, which are activated in their Activate the oscillator for a system for the transmission of several Information by means of a remote control signal in which information is transmitted through the duration of the transmitted signal and other information if it remains the same Frequency of the signal is given by in which of two or more predetermined Time ranges the end of the period is, in particular for an ultrasonic remote control bei- televisions, according to patent application P 24 29 066.2, and consists in that the key switches according to type, the columns and rows of a matrix in groups and Channels are divided, the groups corresponding to the time ranges, da3 after Pressing a key sends a signal characterizing the associated group to a comparator is supplied and the associated channel through the memory content of a memory and that the group is the time domains and the channel is the end the duration determined by the fact that the comparator the Åoutputssigaale one of the Oscillator oscillations counting counter with the signal identifying the group vergeicht, and that, after the count assigned to the group has been reached, the duration of the remote control signal with a constant frequency after one of the Memory content of the memory dependent time has ended.

After pressing a key switch, not only the oscillator is turned on to send the remote control signal switched on, but it is by means of of the memory and the comparator also recorded which of the key switches has been actuated.

The identification of the actuated key switch is done accordingly the identification of an element of a matrix by specifying the column and the row, The columns correspond to the time ranges and the rows to the channels. Of the The comparator determines when the number corresponding to the start of the time range has been reached by oscillator vibrations. From this point on, the Memory queried, which then depends on its memory content, i.e. depending on of the channel, the termination of the transmission of the remote control signal of the previously unchanged Frequency causes. In the manner described by the transmitter according to the invention The transmitted signal can be used by the decoding circuit described in the parent application now the two pieces of information, namely the duration of the signal and the time range, within which the end of the time period lies.

Advantageous further developments of the invention are set out in the subclaims described.

The invention is explained in more detail below with reference to the drawing. They show: FIG. 1 a block diagram of the transmitter according to the invention, FIG. 2 a, Partial circuit diagram of an embodiment of the transmitter according to the invention, in which the Key switches and the oscillator are shown, and the peripheral circuit to the IC containing the actual transmitter and Fig, '3 in conjunction with 4, and FIG. 5 shows the circuit diagram of an embodiment of an inventive and Integrated transmitter.

Corresponding parts are identical in FIGS. 1 to 4 Provided with reference numerals.

In Fig. 1 is a principle block diagram of an inventive Transmitter shown. The key switches S1 to 532 are combined into a matrix 5, eight key switches each through the four lines 1 to 4 (of which the line 2 is not shown in Fig. 1 for the sake of clarity) with one another are connected. These lines practically form the four columns of the matrix 5. The rows of the matrix are formed by the lines K1 to K8. The vertical Lines 1 to 4 are four different time ranges, which are also referred to below as Groups are designated, assigned, while the horizontal lines K1 to K8 eight so-called channels are assigned.

Every button switch, i.e. every remote control command, is through the structure of the matrix 5 is clearly determined by specifying the group and the channel. For example, the key switch S9 is identified by the group I and the Channel K1 (the designation of the four vertical lines 1 to 4 of the matrix 5 is at the same time the name of the group number).

From, the matrix 5 leads the four indicating the respective group Lines 1 to 4 to inputs 7, 8, 9, 10 of an encoder 14.

There is also a comparator 22 is provided that with the two Output terminals 12, 13 of the encoder 14 is connected. At bus corridors 12, 13 of the Encoder 14, the logic signals "1" or "O" occur. It is well known four possible combinations of the two logical signals -t'1 "or" O "are possible, each of which is assigned to one of the four groups. These combinations will be generated by the encoder 14 depending on which of the lines 1 to 4 the actuated key switch is connected. For example, it is the key switch S9 actuated, the information is stored in the comparator 22 that the actuated Key switch is one of group I

The horizontal lines Kl to K8 of the matrix 5, which the channels are connected to data inputs .D1 to D8 of a memory 6. By doing Memory 6 is stored for which of the channels K1 to K8 the key switch operated heard. The key switches S1, S9 and S25 belong, for example, to channel K1. the Numbers after the letter K of the reference symbol give the number below of the channel.

Each group, i.e. each time range, is a certain number associated with oscillator oscillations of an oscillator 15.

For example, group 1 begins and ends after 1600 oscillations after 2880 oscillations. Within this group given by 1280 vibrations there are, for example, eight channels, with one channel through 160 oscillations is marked (8 * 160 = 1230). So if a key switch of group I and operated with channel 1 (here key switch S9), this means that 1600 + 160 = 1760 oscillator oscillations are to be sent out. The full Groups or channels can be selected as follows, for example: Group 1 1600 + n.160 f1 - periods with n = 1, 2, ... 8 Group II 3200 + n.160 f1 - periods with n = 1, 2, ... 8 group III and IV 4800 + m.160 fi - periods with m = 1, 2, .16 While there is a larger gap between groups I and II or II and III (320 vibrations) exists, groups III and IV go directly into one another übe.r, so that on the eighth channel of group III the first channel of group IV without Space connects.

The ossillator 15 in FIG. 1 is used, for example, to generate Ultrasonic vibrations which are emitted via a loudspeaker 16. the Vibrations of the oscillator 15 are fed to the input 18 of a counter 17, which consists of four counter stages Z1, Z2, Z3 and Z4. The four counter levels £ -Z1 bis Z4 are connected in series and form a counter chain, with the carry pulse everyone Counter stage is led to the counter input of the respective following counter stages. The first counter stage Z1 counts up to sixteen in dual code, while the two counter stages Z2 and Z3 are decade counters in the BCD 8-4-2-1 code. The counter stage Z4 is a dual counter, who can count to eight. The outputs 19, 20, 21 of the last counter stage 24 are connected to the comparator 22. It also leads from the counter output for the carry pulse the counter stage Z2 a connecting line via a logic gate G2 to a Input 23 of memory 6.

To further explain the mode of operation, it is assumed that the Key switch S10 is operated. Since this key switch belongs to group T, information identifying group I is sent to comparator 22 via encoder 14 supplied and stored by him. At the same time, the memory 6 recognizes the key switch S10 as belonging to channel K2 and stores this information via its data input D7 off. The oscillator 15 is also switched on indirectly by means of the key switch S10, whose vibrations are emitted from the loudspeaker 16 on the one hand and on the other hand are paid by the counter 17. After 1600 oscillations, i.e. at the beginning of the group I, the count of the last counter stage is Z4 ?? Einsfl. The comparator 11, in which this group I was previously saved, represents reaching the group ' 1 and opens the previously blocked gate G2. Get through this gate G2 now the carry pulses from the counter Z2 to the memory 6. These carry pulses after 160 oscillator oscillations occur, each corresponding to one channel. The one associated with key S10 was previously via line K2 and data input D7 Channel 2 stored in memory 6. The memory 6 now ends the transmission of the Remote control signal whose frequency has remained unchanged after its input 23 a number corresponding to the number of the stored channel of impulses, in this case two impulses, have been supplied. These two impulses but correspond to 320 oscillator oscillations, so two channels. The duration of the transmitted remote control signal therefore sends in the desired manner after 1600 + 320 = 1920 oscillations (corresponds to group I and channel 2).

2-5, the circuit diagram of one embodiment is a Transmitter according to the invention shown for an ultrasonic remote control. Fit same Terminals provided with reference symbols are to be regarded as directly connected to one another. Apart from the frequency considered so far, which remained constant until the end of the period, which is referred to below with £ i, is still used for the ultrasonic remote control a frequency £ 2 generated continuously after the mentioned time is required so two ultrasonic tones of different frequencies £ 1 and £ 2 are emitted one after the other. The? with the first ultrasonic tone of frequency fl in the manner described above defined two pieces of information determine whether a switching function (choice of the TV channel received) or an analog function (e.g. changing the Volume) is to be carried out and which special switching function is to be carried out should be or what type and direction the analog function is. Using the second ultrasonic tone of frequency f2 is then the execution of the previous by - d-i-e command recognized by both pieces of information. The frequency f2 has with the, actual Invention to do nothing in itself. However, it should be mentioned as the oscillator after the end of 'the duration of the' remote control signal with a constant frequency f1 can be switched to frequency £ 2 to carry out the transmitted command got to.

Fig. 2 shows the peripheral circuit to a 10 ', its internal circuit in Fig. 3 to Fig. 5 is indicated the vertical lines already mentioned in Fig. 1 .1, 2, 3 of the matrix 5 lead to base connections of transistors 1 and T2, which- Components of the encoder 14 also mentioned in Fig. 1 are. The line 3 is via a resistor 24 and a diode 25 to the base of the transistor T1 and through a resistor 26 and a Diode 27 with the base of the Transistor T2 connected. The emitters of the two transistors T1 and T2 are direct at reference potential, while their base connections via resistors 28 and 31 with are connected to the reference potential. The base of the transistor Ti is also with of line 2 and the base of transistor T2 connected to line 1. the line 4, which characterizes group IV, is at reference potential. The collectors the transistors T1 and T2 are connected in parallel via resistors 29 and 32, respectively Capacitor 30 or 33 connected to a positive voltage + U1. The collectors of the transistors T1 and T2 also lead to terminals 12 and 13, where the logical signals tlOtl and "1" occur. By convention is a logical one "1" is present when a positive voltage of about + U1 occurs, while in the presence of very little tension or no tension at all a logic 'O' is given. The collector of transistor T2 is still over the resistor 32 is connected to a battery of the voltage + U1, which is a capacitor 34 is connected in parallel, and which is used for power supply.

The transistors T1 and T2 can each be conductive or blocked Assume state. When the transistor is blocked, the one connected to the collector occurs Clamp a logic "1"; while with a conductive transistor a logical "O" given is.

In the idle state, i.e. when all key switches of the matrix 5 are open are, both transistors.T1, T2 are blocked. For example, it becomes a key switch S1 to S8 of group III closed, reaches the base terminals of the transistors 21 and T2 have a positive voltage, whereby they are placed in the conductive state will.

The logic signals "O" appear at terminals 12 and 13.

If, on the other hand, a key switch of group I is pressed, only the Transistor T2 conductive. The assignment of terminals 12 and 13 is then: Terminal 12 = "4", terminal 13 = "O". The assignment of terminals 12 and 13 with the comparator 22 are connected (cf. Sig. 1), thus identifies the group which is assigned to the operated key switch. The identification of the four groups due to the logical signals at terminals 12, 13: Group 1: Terminal 12 = "1"; Terminal 13 = Group II: Terminal 12 = "O"; Terminal 13 = "1" Group III: Terminal 12 = "0"; Terminal 13 = Group IV: Terminal 12 = "1";. Terminal 13 = 11111 The oscillator to generate the ultrasonic vibrations is through a transistor T4, an inductance; 43, a capacitor 44 and a resistor 45 are formed. The top end of the inductance 43 is connected to reference potential via a capacitor 46 and via a capacitor 47 connected to the loudspeaker 16 from which the ultrasonic vibrations are radiated will. A diode 48 and a resistor 49 are connected in parallel to the loudspeaker 16. The collector of transistor T4 is through a capacitor 35 and a resistor 36 connected to the base of a transistor 23, the collector of which is connected to an IZlemne E leads, via which the oscillator oscillations reach the counter. The collector of the transistor T3 is via a resistor 41 with a tap of the inductance 43 and connected to the battery of voltage + U1. From the collector of the transistor T3 also leads a diode 39 to a terminal F, which is connected via a capacitor 40 with reference potential and via a resistor 42 with the battery of voltage + U1 connected is. A resistor 38 and a lead from the base of the transistor T3 Diode 37 after. Reference potential. The diode 37 is used for rapid recharging of the capacitor 35 on a negative edge at the collector of transistor T4.

For power supply of the peripheral circuit and the IC is the already mentioned battery of the voltage + U1 provided. In FIGS. 3 and 4, the lines marked V, those from the terminals connected to voltage- + U1 lead, indicate that all logic circuits of the IC with the in-Fig. 3 to Fig. 5 shown inner circuit with the positive pole of the battery are connected. Only the gate G1 in FIG. 3 is connected to reference potential, see above that initially only this gate G1 is supplied with voltage in the idle state.

If one of the key switches S1 to S32 is operated, then - depending on of the selected group - one, both or none of the terminals 12, 13 on "O" potential placed. The "O" potential at one of the inputs A1 to A8 (FIG. 3) switches the Output I of the NAND gate GI to "1" potential, so that the transistor via terminal I T6 in Fig. 2 switches through. The collector of transistor T6 is across the terminal Ml, with the exception of the NAND gate G1, connected to all logic circuits of the IC, on which the positive pole of the battery + U1 was previously. By switching through of the transistor T6, the emitter of which is at reference potential, and via a resistor 54 is connected to its base, the entire IC is now supplied with operating voltage + U1 supplied.

The inputs A1 to A8 are paired via a Schmitt-T-rigger each connected with exclusive-OR gates. The exclusive-or gates 57 are intended to prevent that pressing two key switches at the same time generates an incorrect command will.

After one of the key switches 81 - S32 has been operated and the whole IC is supplied with voltage, is located on the leading to a flip-flop 58 Connection line 58a is a logical "1F. As long as the oscillator is not yet oscillating, is at the blocking input F of a Schmitt trigger 56 "1" potential, so that the The signal on line 56a is "O" and the output 58b of flip-flop 58 is "Oj '. This signal reaches a start pulse generator 61 via an inverter 62, which generates a short pulse with the potential "1" and then back to "0" potential falls behind. This start pulse sets the counter stages Z1, Z2, Z3 and Z4 (for example of type TL 14520; Dual binary up counter for Z1, Z4 and of type TL 14518; Dual BCD up counter for Z2 and 33) via their reset inputs R and the counter levels -Z5 and Z6 (for example of type TL 14027; dual JK flip-flop) a delay circuit 60 to the zero position. In addition, this impulse arrives via a terminal 74 to the flip-flops 79 and 80 shown in FIG. 4 as well as to a control input 6a of the 8-bit shift register 6. The shift register 6 is loaded in parallel by this pulse, so that one of the data inputs D1 to D8 in the shift register stage which corresponds to the pressed key switch, a "0" signal and "1" signal is stored in the other stages. Simultaneously the information available at terminals 12 and 13 about the selected group with the start impulse taken over by the flip-flops 79, 80 and held. Since the Counter stages Z5, Z6 of the aforementioned delay circuit 60 are reset are, at the output 63a of the NAND gate 63 is the potential? ", whereby the Flip-flop 59 is set in such a way that at the terminal G of the inverter 64 and on the terminal Zeine 11 !! occurs. This turns transistor T4 of the oscillator into Fig. 2 is supplied with base current and begins to oscillate.

The output 81 of the flip-flop 55, the internal circuit of which is shown in FIG is shown is at "0" potential, since the. Output 11 of the shift register 6 has a '11111 and the line 56a has a "0". Thus-is on the terminal H of the NOR gate 65 11l11 potential and the oscillator starts with the frequency Swing 1lb. With the oscillation of the oscillator goes. the potential at the Terminal F of 1111! to O ". The potential on line 56a thus changes from "0" to'-11111. The flip-flop 55 initially retains its position, so that on his Output 81 a 11011 and at terminal H a "1" remains. Gate G1 is over a line 56b is connected to the Schmitt trigger 56. After the A logic "0" is sent to the oscillator (e.g. approx. 0.5 ms) via this line 56b the gate 'G1-, so that the voltage supply of the IC over the switched-through transistor T6 is retained, even if the key switch is actuated is released again.

The oscillations generated by the oscillator are triggered by a Schmitt trigger 66 fed to the input 18 of the counter (counter stages Z1, Z2, Z3 and Z4) and from counted him. The count of the counter stage Z4 is with the position of the flip-flops 79 and 80 in Fig. 4 which show the information associated with the selected group and connected to the comparator 22 via lines J1, j1, $ 2 and are. The output 13 of the comparator 22 is initially at "O" potential. The logical one The signal at the output I3 of the comparator 22 then becomes "1" when the counter stage Z4 reaches a count in which the following logical condition is met; 13 = C + (J.1 +) 3 F2 + j1 e j.2 A.

This results in the above-mentioned association between the logical state of terminal 12 or 13 and the number of times before it appears the "1" potential at the output I3 of the comparator 22 generated oscillations. at Pressing a key switch of group I, a "1" signal appears at the output I3 after 1600 oscillator oscillations, in group II after 3200 oscillator oscillations, in group III after 4800 and in group IV after 6080 oscillator oscillations. The individual groups differ - with the exception of groups III / IV -1600 Vibrations.

The transfer from the counter stage Z3 to the counter stage Z4 takes place during the counting process until the counter Z4 is in position A = "1'i, B = "1" has not yet been reached. If the counter reading A = B = "1" is reached, this takes place the next carry from the other output C3 of the counter stage Z3. This described The effect is achieved by the logic gates 68, 69, 70, 71 and 73. The difference is between group III and IV sonit'only 1080 (8,160 oscillations), while in the other groups it is 1600 (101160) oscillations.

Have so many oscillations been generated by the oscillator that the output I3 of the comparator 22 assumes 1111tPotential, the counter stage Z3 through the logical ")" at terminal I3 for further carry pulses of the counter stage Z2 blocked. The output pulses of the counter stage Z2 now arrive via a NAND gate G2 to the shift input 23 of the shift register 6, so that after every 160 oscillator oscillations a shift command is generated The shift register 6 contains eight cells, where output 11 is the output of the eighth cell. D1 to D8 are the inputs of the Cells. A logic 10'1 entered via one of the inputs D1 to D7 appears after seven to one shift command at output 11, there is an entered "O" with each shift command at input 23 a step (one cell) in the direction of the eighth Cell is pushed further. The data input D8 must therefore always be via the terminal 6b are on logical t'1 ". If a key switch connected to A8 is pressed, then a "0" should appear at output 11 after eight shift commands. this is achieved by using the serial input 6c of the shift register, which is connected to ground 6 an "O" is written, which occurs at output 11 after eight shift commands.

After a number of depending on the pressed key switch Shift pulses appear at the output 11 of the shift register 6 "O" potential. If, for example, a key switch assigned to channel 2 has been pressed, occurs the logic "0" at output 11 after two shift pulses, i.e. after 2.160 = 320 oscillator oscillations. The logical "0" reaches an input 77 of the Flip-flop 55, which now toggles, causing a 't1 "and so that a "0" occurs at terminal H. This acts as a frequency shift key working transistor T5 blocked. At this point is the duration of the transmitted Signal ended with the frequency f1. The oscillator now oscillates at the frequency f2. The transistor T5 switches part of the capacitor Cx when it is conductive the resonant circuit inductance 43 in parallel. This capacity acts as a transformed Parallel capacitance to the capacitance 46, which together with the resonant circuit inductance 43 determines the frequency. So that the transistor T5 does not have a negative collector voltage receives, a diode Dx is connected between Hasse and the collector.

The counter stage is activated by the signal "1" at the output 81 of the flip-flop 55 Z5 of the delay circuit 60 released, so that the following pulses on the Line 67a are counted. If the counters Z5 and Z6 have such a position have achieved that a 'T1' occurs at their outputs 60a and 60b, the toggles Output 63a of NAND gate 63 from “1t 'to“ 0. ”At this point in time, it is the beginning If the key switch is no longer actuated, the set input 59b of the flip-flop is 59 "0" potential and the flip-flop 59 becomes with the appearance of the "0" potential reset on line 63a. This turns off the oscillator. Remain if the key switch is pressed longer (input 59b ~ St1T '), the flip-flop becomes 59 is only reset when the button switch is released. The delay circuit 60 therefore only has the task of being safe with only a brief actuation of a button switch to ask that after generating a certain number of oscillations of frequency f1 the second frequency £ 2 is emitted for a minimum period of time (e.g. 480 oscillations).

The flip-flop 58 can line by a "1" signal on its input 58a can only be set if the potential on line 56b of the Schmitt trigger 56 = "0" (i.e., there is a "1" at input.F of the Schmitt trigger 56) it is achieved that there is a minimum pause between two remote control commands, during which the oscillator does not oscillate. This pause is necessary to prevent tß echoes or reverberations a first remote control command falsify the remote control command immediately following. About that so far Input terminal 76 of counter stage Z1, which has not yet been described, can block it if 480 vibrations are generated after switching to frequency f2.

If two key switches are pressed very quickly one after the other, so the first command - as described above - is executed first. When letting go of the key switch toggles the flip-flop 58, so that at the input 59b of the flip-flop 59 a 11111 is because the potential on line 58a is set to. Will now If another key switch is pressed immediately, then the "1" potential is again on line 58a. The flip-flop 58 remains in the tilted back position as long as the potential on line 56a of Schmitt trigger 56 = ll1ll, i.e. until the first command executed and a certain time passed after the oscillator decayed is. The potential on line 56a then becomes "0" and flip-flop 58 can tilt, which means a "0" is on line 58b. This becomes an expensive start-up impulse generated and the second command issued.

The invention is not limited to the embodiment described for an ultrasonic remote control is limited to a television set. Rather, they are There are also other possible uses, e.g. with a remote control for one Radio receiver.

Claims (15)

P a t e n t a n s p r ü c h e 1. Transmitter for remote control signals from one in its frequency switchable oscillator can be generated, and with the desired remote control functions assigned key switches that switch on the oscillator when pressed, for a system for the transmission of several pieces of information by means of a remote control signal, in which one information is given by the duration of the transmitted signal and another Information at always. constant frequency of the signal is given by in which of two or more predetermined time periods the end of the time period is, in particular for an ultrasonic remote control in television sets, according to patent to message P 24 29 066.2, characterized in that the key switches (S1 - S32) 'after The type of columns and rows of a matrix (5) are divided into groups and channels, where the groups correspond to the time ranges that clicked after pressing one a signal characterizing the associated group is fed to a comparator (22) and the associated channel is identified by the memory content of a memory (6) and that the group is the time domain and the channel is the end of the time period thereby determines that the comparator (22) the output signals of one of the oscillator oscillations counting counter (17) with the signal identifying the group compares, and that, after the number assigned to the group has been reached, the duration of the remote control signal of constant frequency according to one of the memory contents of the memory (6) dependent time has ended. 2. Transmitter according to claim 1, characterized in that four groups are provided, and that the groups each by one of the four possible combinations of the two digital signals "O" and tta are marked in t. 3. Transmitter according to claim 2, characterized in that two switching transistors (T1, T2) are provided, on whose collectors in the conductive state the d-digital Signals "0" and in the locked state the digital signals "1" can be tapped, and that upon actuation of the key switches (59-316) of the first group of the one ransistor (T2), when pressing the key switch (S 17 -24) of the second group the other transistor (Tl) and when you press the key switch (S1 - S8) the third group both transistors (T1, T2) are activated. 4; Transmitter according to Claim 2, characterized in that the two digital signals are fed to the comparator (22) via a flip-flop (79, 80) each will. 5. Transmitter according to claim 1, characterized in that the memory (6) is an n-bit shift register, where n represents the number of channels (K1 - E8), that a memory cell of the shift register is assigned to each channel (K1 - K8), and that after pressing a key, the signal "O" in the memory cell of the associated Channel and the signal "1" is transferred to the remaining memory cells. 6. Transmitter according to claim 1, characterized in that the counter (17) formed by a counter chain consisting of four counter stages (Z1 - Z4) is that the first counter stage (Z1) after sixteen counting pulses 1md dWe second and third counter stage (Z2, Z3) a carry pulse after every ten counting pulses to the next counter level, and that the last counter level (Z4) is a 3-bit binary counter whose outputs (A, B, C) are connected to the comparator (22) are. 7.- transmitter according to claim 5 and 6, characterized in that the Carry-over pulses from a counter stage (Z2) arranged in front of the last counter stage (Z4) the loop input (23) of the shift register (6) via a logic gate (G2) can be supplied, and that the logic gate (G2) for the carry pulses is driven by the comparator (22) permeable when the counter reading with the comparator (22) connected counter stage (Z4) assigned to the beginning of the group Counter reading is. 8. Transmitter according to claim 7, characterized in that the output (11) of the shift register (6) is connected to an input (77) of a flip-flop (55) is, and that with a logical ttO't at the output (11) of the shift register (6) at the output (81) of the flip-flop (55) a logic "1" occurs, and that means the logic fllit the frequency of the oscillator (15) can be switched. 9. Transmitter according to claim 8, characterized in that a delay circuit (60) is provided, which causes the oscillator (15) after switching on another frequency during one determined by the delay circuit (60) vibrates on the other frequency for a minimum period of time. 10. Transmitter according to claim 9, characterized in that the delay circuit (60) contains a counter (Z5, Z6) to which the carry pulses from before the last Counter stage (Z4) arranged counter stage (Z2) are supplied, and that said minimum duration given by a selectable count of the counter (Z5, Z6) is. 11. Transmitter according to claim 1, characterized in that a start pulse generator ' (61) is provided, which after actuation of a key switch (S1-532) a Pulse generated, and that the counter (17) is reset by this pulse, the memory (6) is loaded, the signals characterizing the group X are sent to the comparator (22) are supplied via a flip-flop (79, 80) each and the oscillator (15) is started will. 12. Transmitter according to claim 1, characterized in that an IßAND- gate (G1) is provided whose inputs via the between the positive pole (+ U1) a voltage source and reference potential (M) switched key switch (51 - S32) can be connected to the reference potential (M), and that the output (I) of the NAND gate (G1) controls the base of a transistor (T6) whose emitter is connected to the reference potential (M) is connected, and which, in its conductive state, the other logic circuits of the transmitter, which are connected to the positive pole (+ U1), to the reference potential (M) switches on, whereby the entire transmitter is activated after pressing a key switch (S1 - S32) is supplied with operating voltage. 13. Transmitter according to claim 12, characterized in that another Input of the NAND gate (G1) with an output (56b) of a Kipy'r circuit (56) is connected, the input of which (Fj in the quiescent state "1" potential and after the decay of the oscillator has "0" potential, so that the further input of the NÄND gate (G1) after the oscillator (15) has started to oscillate, a corresponding to the reference potential (M) logical "O" is supplied, which means that the transmitter remains active even after a vast switch has been released (S1 -S32) remains supplied with operating voltage. 14. Transmitter according to claim 11, characterized in that the start pulse generator (61) can be controlled by the key switches (S1 - S32) via a flip flop (58), and that the flip-flop (58) is in, depending on the operating state of the oscillator (15) controls the start impulse generator (61) in such a way that this only when not oscillating oscillator is capable of generating a pulse, so that between two remote control commands a minimum pause to avoid the interference of Echoes and reverberation is given. 15. Transmitter according to claim 1, characterized in that in pairs two pushbutton switches (S1 - S32) each on the inputs of an exclusive 0DER gate (57) are performed, the outputs of which are in pairs each with a further exclusive OR gate (57), the outputs of which lead to a further exclusive OR gate, at its Output is tapped when a key switch is pressed "1" potential, \ where is avoided by the mentioned exclusive-OR gate (57) that with simultaneous Pressing two key switches generates an incorrect remote control command. L e r s e i t e