DE2023664A1 - Remote control device - Google Patents

Description

7004-70 Kö ,. S.
IiC /. f-19 2 "
Convention Date:
May'14, 1960

IiCA Corporation, Mew York, N.Y., V.St.A.

Ferr control device

The invention relates to a control device, in particular a .St-örschutzschal timr-7 for an ultrasonic television. your establishment for electronic devices.

J-, κ various types of wireless''erri-Kteuorc-iinrichtiingen have already been pre-; sclll,'if; en, in which a local transmitter fej-Ufjtische control signals. radiates predetermined frequency, which are received by a remote ε.η device arranged and control this. a

Such devices are used, for example, for operational control from remote radio or television receivers used by enabling the listener or viewer to remotely adjust the tuning, volume, etc. In general the acoustic vibrations are generated with discrete frequencies, the number of which corresponds to the number of remote-controlled functions in the Device corresponds. The generated vibration is recorded by a remote control pickup device detected in the device, and the then generated electrical signals are the remote control device of the device.

One that occurs in such remote control devices

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The problem is that the remote control circuitry can be erroneously actuated by numerous noises that usually occur in a household. It must therefore be ensured that the remote control device is not operated incorrectly by external signals which can be generated, for example, by jingling keys or coins or by ringing telephones. It is known to achieve such a lack of susceptibility to extraneous noise by using frequency-selective filters and by using mechanical relays themselves. However, since foreign signals of this type generally contain frequency components that are close to the useful frequencies generated and can also persist beyond the delay time, incorrect actuation by foreign signals is not prevented to a satisfactory extent in these known interference suppression circuits.

To avoid this disadvantage, according to the invention, a Remote control device having an arrangement for generating an output signal upon receipt of signals generated at a remote location and with a control device coupled to the signal generator arrangement for controlling the functions of the device in question provided, which is characterized by a detector circuit which detects the presence of any amplitude changes the output signals of the signal generating device perceives, as well as by a blocking arrangement, which upon perception of amplitude changes prevents the control of the relevant device function in the output signal.

The invention is explained in detail below with reference to the drawing, the single figure of which is partially in block form shows reproduced circuit diagram of a remote control device according to an embodiment of the invention.

A transmitter 10, which can be a hand-held transmitter, transmits acoustic signals or tone control vibrations. Such a transmitter includes one Transistor oscillator which is operated by pressing a button or switch so that it is active during the time when the button or Switch is pressed, one of eight different ultra-

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generated sound control frequencies. The eight frequencies are in the range from 34 to 45 kHz. The control signals are transmitted through a sound transducer and by means of an integrated one Amplifier circuit 14- connected microphone 12 added. The special design of the amplifier used is not critical. The integrated amplifier circuit used in the present case 14 is detailed in U.S. Patent 3,423,725 described. In contrast, there are slight changes in the preamble in the present integrated amplifier circuit Order made xvorden, since to increase the Oe including amplification yet another discrete amplifier stage 16 is added. | !. ■ he output stage of the integrated circuit is in the case of the mentioned USA-Pate nt grinds for the C-amplifier operation, on the other hand in the this case biased for A-amplifier operation.

The output signals of the amplifier circuit appearing at a connection contact 18 are fed to the primary winding 20 of a Trane format number 22. The secondary winding 24 of the transformer is coupled to the television signal handling and control circuit 26. A varistor 28 (a non-linear voltage-dependent resistor, the value of which decreases with increasing voltage) is connected across the primary winding 20 and prevents needle-shaped voltage pulses from occurring on the winding, which can lead to the breakdown of the transistor 36. %

The primary winding 20 is connected via a resistor 30 to a terminal 32 to which a! '+ - supply voltage can be fed. The resistance is bridged for signal frequencies by a capacitor to a fixed reference potential (ground). Typical frequencies used in remote control devices of the present type are in the range of about 34 to IIIz. The IH supply source supplies the collector-F.mitter path of the amplifier transistor 36 with P operating current via the resistor 30 and the winding 20. The base of the transistor is connected to terminal 32 via the resistor 3 ^. The circuit elements are selected and dimensioned in such a way that in the idle state, ie when the transmission signal is not present, the transi. <; (Or .] (, In the Saturation.szu.si and

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is biased.

When through, the microphone 12 receives a desired ultrasonic control signal is recorded, is the, then generated electrical see signal amplified and dem. usually saturated located amplifier 16 is supplied. Me negative half-waves of the amplified signal oscillation have a sufficiently large amplitude, to turn off transistor 36, and they cause the mainly by the inductance of the primary winding 20 and the capacitance of the voltage-dependent resistor 28 is formed Oscillating circuit oscillates dampened. At the resonance frequency of the oscillating circuit is about 100 kHz «

The oscillating circuit 20-28 is per period of the supplied signal oscillation a positive output pulse is generated. The negative-going parts of the oscillating signal are caused by the power line of the collector-base junction of the transistor 36 is attenuated.

A resistor 21, a diode 23, a capacitor 19 and a capacitor 34 are connected via the primary winding 20 Series circuit switched. The first few positively directed oscillation impulses are through this low ohmic, the, Capacitor 19 attenuated charging circuit.

The periodic blocking of the transistor 36 by the amplified control signal has the consequence that the mean current in the resistor 30 decreases. The voltage at terminal 42 therefore increases from essentially zero in the positive direction. The speed The speed of this increase in voltage is determined by the time constant of the resistance 30 and the capacitor 34 are determined. This short-term The rise in voltage at the terminal 42 is indicated via the capacitor 44 as single positive pulse transmitted to diode 50. The diode 50 conducts so that the capacitor 54 moves in a positive direction charges. If the voltage on capacitor 54 is sufficiently positive, the transistor 52 is conductive, so that. the capacitor I9 calibrate discharges and thereby the volatile oscillating waves according to mass be derived. If the positive «? Tension rise on the little one 42 becomes less steep, diode 50 is gtiped. . This reet-

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borrowed charge voltage of the capacitor 54 discharges through the base emitter stretch of transistor 52, after which transistor 52 is blocked "will.

Make the point in time when transistor 52 turns off the Sehwiaagungsimpulse on the primary winding 20 through the Circuit with the diode 23 attenuated until the capacitor 19 is charged is.

The processes just described take about 100 milliseconds, after which on the primary winding 20 and the secondary winding 24 essentially undamped oscillation pulses for the supply line to the control circuit 26 are generated. By increasing the f mean current conduction of transistor 36, the current conduction becomes of transistor 52 is not affected. If on the other hand the power line decreases in transistor 36 with a sufficiently large rate of change, if this is perceived and thereby the transistor 52 is conductive, made so that the oscillation pulses on the primary winding 20 be dampened away. The resistor 21 provides sufficient insulation to prevent the voltage at the terminal 42 is seriously affected by the current conduction of transistor 52.

As mentioned, contain external signals, for example from jingling Keys, ringing coins and ringing telephones, frequency components that are within the passband of the remote control device lie. As described in the aforementioned United States Patent ™, the remote control amplifier circuit is a achieved extensive insensitivity to such external signals. However, since these extraneous signals often contain powerful components, which are close to the frequency of a useful control signal, it can happen that the control circuits are operated incorrectly. Since the external signals also contain other frequencies in addition to the frequencies close to the useful signal frequency due to the non-linear interaction between the different Components of the external signals Beat components «it lower Frequency generated. All consequence of this is the repetition rate, with which the transistor 36 is switched off or blocked, =

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modulated by these lower frequency beat components. The time constant of the RC element 30, 34 is dimensioned so that signals in the range from 20 Hz to 10 kHz, which are perceived or rectified by the circuit with the diode 50 and used to turn transistor 52 on. if the transistor 52 is turned on, will be across the primary winding 20 occurring oscillation pulses attenuated, so that it is prevented that the external signals the control circuits 26 incorrectly actuate.

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Claims (9)

• 2Ü23Ö.64 - 7 claims Li.) Remote control circuit with a first circuit arrangement for generating output signals when receiving from a distant Place generated signals as well as to the first circuit arrangement coupled control circuits for controlling functions of the remote-controlled device by a detector circuit (30, 34, 44, 46, 48, 50, 54), which the occurrence of amplitude changes in the output signals perceives, and by a coupled to the detector circuit Locking circuit (19, 21, 23, 52), which upon perception of Changes in the amplitude of the output signals prevent the device functions from being controlled by the control circuits (26). 2. Remote control device according to claim 1, characterized characterized da0 the blocking circuit (19, 21, 23, 52) contains a three-electrode component (52), which with its first and its second electrode between the output of the first circuit arrangement (12, 14, 16) and a reference potential point coupled and in the conductivity of its current path between first and second electrodes coupled to the output of the detector circuit (30, 34, 44, 46, 48, 50, 54) via one Control input is controllable. 3. Remote control device according to claim 2, characterized characterized in that the detector circuit (30, 34, 44, 46, 48, 50, 54) one between the first circuit arrangement and a diode (50) coupled to the control input. 4. Remote control device according to claim 3, ge ken n records by one coupled to the diode (50) Capacitor (34), which prevents high-frequency signals pass through the diode. 5. Pernsteuereinrichtung according to claim 2, characterized e g ken nzeichnet because · the blocking circuit (19, 21, 009847/1357 23, 52) a capacitor coupled between the first electrode of the three-electrode component (52) and the reference potential point (19) contains. 6. Remote control device according to claim 5 »thereby marked «that the blocking circuit (19, 21, 23, 52) the series circuit coupled between the first circuit arrangement (12, 14, 16) and the three-electrode component (52) a resistor (21) and a diode (23). 7. Remote control device according to claim 6, characterized in that the three-electrode component (52) is a transistor. 8. Remote control device according to claim 2, characterized in that the detector circuit (30, 34, 44, 46, 4S ₅ 50, 54) with its .Eingang to the connection point between the primary winding (20) of a transformer (22) and οinem resistor ( 30), which are connected in series between the output of the first circuit arrangement (12, 14, 16) and an operating voltage source, is connected j that the secondary winding (24) of the transformer is coupled to the control circuits (26) j that between the first electrode of the three-electrode component (52) and the reference potential point a first capacitor (19) is coupled that the series connection of a second resistor (21) and a first diode (23) between the end of the primary winding (12, 14, 16) connected to the first circuit arrangement ( 20) and the first electrode of the three-electrode component (52) is connected} and that between the first resistor (30) and the control input of the three-electrode component (52) a second diode (50) is coupled. 9. Remote control device according to claim 8, characterized (· El · indicates that between the tax receipts of the three-electrode component (52) and the ReferenzspeteiH-! -.Ipmict a second capacitor (54) is coupled, and that between the ii'sten resistor and the reference potential point a third capacitor (34) ■ is coupled, 009847/1357 BAD OBIQfNAL