DE2735502A1 - Remote control ultrasonic signal transmitter - has capacitors connected to tuned circuit of oscillator over diode and via switches - Google Patents

Abstract

The ultrasonic signal transmitter can be used for the remote control of TVs, domestic lighting, etc. It consists of an oscillator circuit coupled to a parallel tuned circuit. Switches connect and disconnect capacitors to and from the tuned circuit in order to generate different frequencies, and switch on and off supply voltage to the oscillator circuit. It also includes an ultrasonic transmitter. Each of the connectable capacitors (17, 18) is connected to the tuned circuit (8-10) through a diode (14, 16), and can be connected to a.c. wire to the tuned circuit through a switching component (11-15) with only one current path. The switching component also connects the ultrasonic transmitter (20) directly to the tuned circuit.

Description

Remote control transmitter

The invention relates to a remote control transmitter for sending ultrasonic remote control signals, consisting of an oscillator circuit with a coupled parallel resonant circuit and with switches, with their help to generate different frequencies capacities can be switched on and off to the parallel resonant circuit and with the help of which the supply voltage to or to the oscillator circuit. can be switched off, and from an ultrasonic transducer.

Wireless remote control devices have been around for quite a while Time for remote control of moving objects such as cranes, locomotives, Model airplanes or toy cars. Recently, remote control devices are found with infrared or ultrasonic waves also input into the installation technology for Switching the living area lighting on or off. In the variant as a dimmer and wirelessly regulate the brightness of the lamps remotely. Known for a long time are wireless remote control devices also for devices in the entertainment industry, especially for devices with increased ease of use. Various continuously Changeable setting parameters, such as volume, contrast, color saturation, the brightness, etc., or the setting variables that can be changed in discrete steps, like the station search and the station selection, can be done through the wireless remote control to be changed. An ultrasonic signal emitted by a transmitter is used for this purpose, in a receiving part into a control signal corresponding to the selected frequency is converted.

When using remote control devices with ultrasonic waves various methods are already known. The simplest procedure is to that each setting variable has a special channel with its associated frequency Identification of the type of setting variable is assigned. With the continuously changeable Setting variables are usually two frequencies for changing the setting variables requires one frequency for increasing and one for decreasing Setting variable. The amount of change desired is determined by varying the length of time Set pressing an enter key. On the receiving end are used to generate of the various frequencies a number of corresponding to the number of frequencies Resonance circles are used, which is a time-consuming process before the receiver is put into operation Make the adjustment process necessary.

An ultrasonic remote control is already known in which the Encoder is designed in a 5-channel version with an LC oscillator. The frequency-determining ones Limbs are inductances and capacitances, with the different frequencies generated by connecting additional capacities to the resonant circuit by means of a switch will. The switches are designed with two poles. One of the contacts switches the Additional capacitance to the resonant circuit, while the other contact supplies the operating voltage turns on. The switches consist of leaf springs that sit directly on a copper foil the printed circuit is pushed to the left or right via a wedge individual Connect contact tracks with each other. Due to the shape of the copper foil, when pressed first switch the correct additional capacitance parallel to the resonant circuit and then the operating voltage is switched on. This is to prevent When the device is switched on, a frequency other than the desired frequency is transmitted. This would be the case if the operating voltage was switched on first Oscillator at its base frequency and only when the additional capacitance is switched on would vibrate at its desired frequency. About clear switch-on and switch-off conditions to have is this temporal staggering of the contacts when switching on and also required when switching off. The disadvantage here is that the design effort for a two-pole switch is relatively high, especially since the contacts are timed must be connected in series to be sure that no malfunctions are triggered will. In addition, the space requirement of such a two-pole switch is opposite a single pole switch higher because the electronic ones are still on the printed circuit Components must be accommodated and the housing of the encoder is still a handy one Should have format.

The object of the invention is therefore to avoid these disadvantages and for a remote control transmitter of the type mentioned above, a simple electronic one To find circuit, so that the switch can be single-pole or only must have a current path.

This object is achieved according to the invention in that each of the or capacitances that can be switched off via a diode with the ParallelS0hWflSkrCts trbUnd is and via a switching element having only one current path in terms of alternating voltage can be connected to the parallel resonant circuit is, with the switching element at the same time the ultrasonic transducer is connected directly to the parallel resonant circuit will.

Further advantageous refinements of the invention emerge from the subclaims.

The invention and further details are described below for three Embodiments illustrated and described in more detail with reference to the drawings.

Of the figures, FIG. 1 shows a circuit diagram of a remote control transmitter a single pole mechanical switch, Figure 2 is a circuit diagram of a remote control transmitter with sensor electrodes, Figure 3 is a circuit diagram of another remote control transmitter with sensor electrodes in another embodiment.

As an oscillator for generating sinusoidal oscillations was made for everyone three exemplary embodiments, a Hartley oscillator was chosen. Of course you could other types of oscillators can also be used. The Hartley oscillator is made from a transistor 1, whose collector is connected to the primary winding of a transformer 8 and is fed back to the base via a capacitance 6. The base is over a resistor 2 and a diode 3 to ground. The emitter of the is also connected to ground Transistor 1. The base is also connected via a resistor 4 to point a of the circuit placed, which in turn is connected to ground via the capacitance 5. With the point a is a tap connected to the primary winding of the transformer 8, so that a inductive three-point circuit results. The feedback voltage will led to the base via capacity 6. Is now at point a supply voltage placed, the oscillator begins to oscillate. The part that determines the frequency of the oscillator consists of a parallel resonant circuit that runs through the secondary winding of the transformer 8 and a number of capacities is formed by mechanical or electronic switches with alternating voltage to the parallel resonant circuit. or can be switched off.

In Figure 1 is an embodiment with mechanical switches 11, 13 and 15 shown. These are single-pole short-stroke switches, whereby one connection is connected to the supply voltage, while the other connection is connected via a diode 12 or 14 or 16 to point a of the circuit. The capacities 9 and 10 are parallel to the secondary winding. With the switch 13 can be the capacity 17 and with the switch 15 the capacity 18 can be added to the capacitors 9 and 10 are switched to the parallel resonant circuit.

A transmitter 20 serves to emit the ultrasonic frequencies Via a parallel-connected diode 19 to the supply voltage UB 7 and via a Capacitance 21 is at point b of the circuit. So that the frequency of the emitted Ultrasonic waves are the same as the frequency generated by the oscillator a polarization voltage is applied to the encoder 20, on which the alternating voltage is superimposed.

The polarization voltage is obtained by rectifying the alternating voltage generated.

If, for example, the switch 11 of FIG. 1 is closed, then Via the diode 12 supply voltage is applied to the oscillator and it begins to swing and although at a frequency generated by the secondary winding of the transformer and the capacities 9, 10, 20 and 21 is determined. Because the point b is the hot point of the circuit, the positive half-wave loads Oscillation the capacities 17, 18 and 21 to a positive potential compared to the Points c and d. The diode is conductive, so that the capacitance of the transmitter 20 is short-circuited. A reloading of the capacities 17 and 18 can be done with the negative Half-wave does not occur because the diodes 14 and 16 are then blocked. This means, that no alternating current flows through these capacities, and thus they do not determine the frequency are involved in the vibration. The attenuation by the reverse current of the diodes 14, 16 is negligible. At the encoder 20 is now the negative half-wave Oscillation and in series with this the potential of the capacitance polarized in the same direction 21.

The voltage at the encoder 20 at point d of the circuit fluctuates accordingly between the value zero and twice the negative peak value back and forth here.

If, for example, switch 13 is now closed, the diode 14 Supply voltage is applied to the oscillator and it begins to oscillate and although at a frequency that is determined by the secondary winding of the transformer and the Capacities 9, 10, 17, 20 and 21 are determined.

The point c of the circuit is on when switch 13 is closed a positive potential that is determined by the supply voltage UB. The point a is approximately up to the voltage drop caused by the diode 14 on the same potential. At point c of the circuit is with open switch 15, similar to point d, a negative DC voltage, that of the resonant circuit generated vibration is superimposed. Since the diode 16 is blocked, the capacitance is 18 not connected to the parallel resonant circuit.

In the embodiment shown in Figures 2 and 3 one Remote control transmitters are the mechanical switches by electronic switches replaced. Otherwise, the remaining part of the circuit also corresponds in its mode of operation the embodiment described in Figure 1.

The electronic switches of Figure 2 consist of two in cascade connection Transistors 22 connected in series in a so-called Darlington circuit and 23 or 24 and 25 and 26 and 27. The emitter of transistor 22 is connected to the positive Pole of the supply voltage placed while the collectors of the transistors 22 and 23 are connected to one another at the anode of the diode 12. The base of the transistor 22 is connected to the emitter of transistor 23. The base of this transistor 23 is via the sensor electrode 28 to the negative pole of the supply voltage placed. When the sensor electrode 28 is touched by a finger, the base becomes of transistor 23 is connected to ground, so that both transistors 22 and 23 be switched through. The transistors 24 and 12 also switch in the same way 25 or 26 and 27 as soon as the sensor electrodes 29 or 30 are touched.

In Figure 3 is another embodiment of an electronic switch shown, which can also be actuated by sensor electrodes. A transistor 40 is then switched through when its base on the sensor electrode 31 to positive Is placed pontentially. The emitter of this transistor is connected to ground and its collector is connected to the base of a further transistor 34 via a resistor 37. The collector of transistor 40 is also connected to ground via a capacitance 43. If the transistor 40 is now touched Sensor electrode switched through, so approximately ground potential is applied to the base of the transistor via the resistor 37 34 placed. The transistor 34, whose collector with the anode of the diode 12 and its Emitter is connected to the positive pole of the supply voltage UB, switches thus through. Since the transistor 40 under certain circumstances when touching the sensor electrode 31 switches through at mains frequency, the capacitance 43 serves to smooth the control voltage for the following transistor 34. The mode of operation of the other two electronic ones Switch, consisting of sensor electrodes 32 and 33, transistors 41, 42, 35 and 36, the resistors 38 and 39 and the capacitors 44 and 45 is completely analogous.

Claims (5)

Claims S remote control transmitter for sending ultrasonic remote control signals, consisting of an oscillator circuit with a coupled parallel resonant circuit and with switches, with their help to generate different frequencies capacities can be switched on and off to the parallel resonant circuit and with the help of which the supply voltage can be switched on and off to the oscillator circuit, and from an ultrasonic transmitter, characterized in that each of the capacitances (17, 18) that can be switched on or off is connected to the parallel resonant circuit (8, 9, 10) via a diode (14, 16) and via a switching element with only one current path (im, 13, 15, 22 to 45) AC voltage can be connected to the parallel resonant circuit, with the Switching element at the same time also the ultrasonic transmitter (20) directly to the parallel resonant circuit is switched on. 2. Remote control transmitter according to claim 1, characterized in that that the diodes (14, 16) with their cathodes lying parallel to the parallel resonant circuit are connected. 3. Remote control transmitter according to claim 1, characterized in that that the switching elements have short-stroke keys (11, 13, 15) as single-pole switches. 4. Remote control transmitter according to claim 1, characterized in that the switching elements sensor electrodes (28 to 30) with a subsequent Darlington circuit (22 to 27). 5. Remote control transmitter according to claim 1, characterized in that the switching elements from sensor electrodes (31, 32, 33), an amplifier stage (40, 41 42) and a downstream transistor (34, 35, 36) exist.