DE2019154A1 - An oscillator that can be set up in the form of an integrated circuit, especially for an acoustic warning system - Google Patents

Description

An oscillator that can be built up in the form of an integrated circuit; especially for an acoustic one

Warnaystem.

The invention relates to an oscillator which can be constructed in the form of an integrated circuit, with a second identical oscillator which can be built up in the form of an integrated circuit is provided, which is between the supply voltage source and the voltage connection of the first The oscillator is able to produce a pulse or intermittent external load voltage.

Integrated oscillators are particularly useful with acoustic Alarm systems of use because of the inherent in them Advantages such as small size are diminished Power requirements and economical production as well increased reliability. With the previously boku ^ If the alarm system is active, a continuous tone or a continuous warning signal is usually generated » such warning signals are generally sufficient for most cases. Under some environmental conditions with a noise background, however, is a continuous «; preferring sound or a continuous sound, which of which is previously known from systems generated.

10 9 8 11/12 7 6

thinking .

thinking, there namely the desired alarm signals opposite obscured by the background noise of the surroundings or covered by background noise. Obviously, this can be background or environmental noise very difficult to modify, so that it is necessary to generate an improved acoustic signal. It was found that under many environmental conditions at which the background noise cannot be controlled or controlled are, a pulsed or intermittent acoustic Signal very borrowed from the human ear can.

A major consideration in the manufacture of audible alarm systems of the type described herein relates to size, weight, and cost of manufacture. In principle, integrated circuits meet these conditions. The invention provides improvements over conventional acoustic alarm systems, while at the same time the; in the foregoing conditions relating to size, etc., are met. This is achieved in that a circuit is connected to the supply voltage terminal of a Troiber oscillator, to the output of which a resonance converter is connected, so that when a voltage is supplied to the oscillator, the oscillator repeatedly pulses the supply voltage, producing an interrupted acoustic signal is generated at the resonance converter. It should be noted that a major feature of the improved system ³ is that the circuit's oscillator is the same as the TiBiber oscillate Qr which operates the tone transducer except for the external resonance components in each load circuit. In the present case, the external components are the EC elements in the load circuit of the switching oscillator and the resonance converter in the load circuit of the driver oscillator. Components are of common construction and are at

109811/1276

described

described embodiment is not integrated, while the rest of the switching oscillator and the driver oscillator are designed as complete integrated circuits. Obviously, expensive design and manufacturing problems that occur with the technology of modern integrated circuits are eliminated to a large extent by the use of identical circuits in the switching and driver oscillators of the system, with improved results at the same time. intermittent or pulsed acoustic signal can be achieved at the output of the driver oscillator.

It is an object of the invention to provide an improved driver oscillator to create, in which a switching oscillator is used at the voltage input terminal, such that, if a resonance converter with the output of the driver oscillator connected, this transducer oscillates in an intermittent or pulsed manner «,

Another object of the invention is to provide an improved, in the form of an integrated circuit buildable oscillator produce, wherein a switching device is provided which switches in an adjustable or controllable cycle and which is connected to the supply voltage connection of the oscillator «

A further aim of the invention is to provide an improved, in Form an integrated circuit buildable oscillator to create, with a second in the form of an integrated Circuit buildable oscillator of the same structure is provided that between the supply voltage connection terminal and the voltage source is switched on.

Another object of the invention is to provide an improved, in the form of an integrated oscillator that can be built up

10 9811/1276

■ - .., - goal

A-

provide toT ^ can be used in conjunction with a resonance converter ₅ wherein eiae switching device _S is provided which is connected to the voltage source such ISS ₈ that an intermittent or pulsed AKU · = stisches signal generated by flea resonant converter. * "irö _o

Can warden It is further object of the invention to provide an improved free assembly as an integrated circuit oscillator vorzuse = JiSSi ₉ ä © r in combination with a resonant converter vorwendet, "to form an acoustic alarm system, WO =! In this oscillator ein® scarf te in order to intermittently or periodically guide a voltage to the oscillator

The invention is to be explained in the following description under on the drawing,

Ia the drawing EIA Ausfüliriingsbeispiol ERT is shown indung, which is used in a trajgbaren, of miniaturization = overbased acoustic alarm device ₀ The transducer Xi is a piezoelectric crystals may, however, other types of resonant converters ^ instead of this crystal, werdeB used. _o The circuit ,, designated sit ,, I is to intermittent or periodic pulses supplied to the switching device, the effective ISTJ the SpeI sespaximmgsanschluß- ~ 4 ⁸ of the oscillator. 2 It should be noted that the switching device i is an oscillator. "An essential feature of the invention is that the solialt" = 0 @ gillator i (with the exception of the external components Ei and Ci in the circuit i and the resonance converter Xi in the oscillator) are identical. With the circuit there is a driver oscillator S and this avoids unnecessary manufacturing costs. HI and C1 are preferably miniaturized components which are arranged outside the IC section of the circuit and are therefore classified because of their

1098 11 / 1-2 78. values

8AD

Values different depending on the resonance frequency can be, with which the switching device should swing " If - in other words - a longer tone or a If a longer acoustic signal is desired on the transducer Xl, the fourth of -Rl and Cl can be modified accordingly, to change their time constant. The external components IiI and Ci act as feedback for the Sehalt oscillator 1, while the converter Xl as feedback for the driver oscillator 2 acts. A piezoelectric transducer is used as the feedback Xl of the driver oscillator 2 preferred because of its electro-mechanical properties, which allow it, as a charging-discharging device and to serve as a sound generator. '...-.

It should be noted that the switching oscillator 1 operates in essentially the same way as the driver oscillator 2. Each circuit has a resonant load connected to its output, namely Rl and Cl in circuit 1 and Xl in circuit 2. With this in mind, the detailed discussion can be limited to circuit 1, it being noted that the corresponding components in circuits 1 and 2 have the same reference numerals with the exception that the elements in circuit 2 with an " ^l " next to marked with the reference number.

The collector load circuit 3 of the transistor Q2 has a Transistor Q3 of the same polarity type (NPN) as dor Transistor Q2 on. The collector of transistor Q3 takes a voltage directly from the voltage source Bi at the feed »« Voltage connection on. The emitter dos transistor Q3 is to the collector of transistor Q2 through an isolating diode Ü3 connected. A fixed resistor R5 with a relatively high resistance value generates both a base bias for the transistor Q3 as well as a collector

10 9811/1276 preload

BATH

bias voltage for the transistor Q2 _O The resonance circuit Ei and Gl is connected to the load circuit 3 and lies between the resistor S3 end of the base and the transistor Q1, ¥ / odiaroh the SölialteinrielitKng i like an oscillator arfeei = tea. It should be noted _s' let the impedance of the collector = load circuit 3 by öen state of the transistor Q2 overall = is controlled ο ¹ KTeEa the transistor Q2 is highly conductive, then a large voltage drop across the resistor R5 and the base exists of Lastschaltungstranslstors Q3 is thereby biased to prevent transistor Q3 from conducting. This non-conductive state of the transistor Q3 or this high resistance state of this transistor prevents the undesired flow of a current through the resonance circuit Ri-Cl during this time and, on the one hand, the efficiency is increased as a result. On the other hand, the efficiency is further increased because the high resistance of the resistor R5 prevents a large amount of current from flowing through the conductive transistor Q2.

In the other state, when transistor Q2 is non-conductive, it is desirable that the impedance of the load circuit 3 is low in order to reduce the power consumption in this circuit to a minimum, while a maximum Current passes through the resonance load Ri-Cl. This effect is due to the non-conductive state of the transistor Q2 or by the high resistance state of this transistor, which has a sufficiently low voltage drop at resistor R5 while transistor Q3 is biased into its conductive state and while Bl directly with the resonance load balance Rl-Cl over the current limiting resistor R3 is connected. The diode D3 prevents a base emitter course bottom in that this forms a high resistance for a current flowing from the base electrode to the emitter electrode of the transistor

109811/1270 £ 3

BATH

Q3 wants to flow. It should be noted that the diode D3 is connected with the opposite polarity to the transistor associated with the Eraitter-Basisöiode fles. In this way, the diode D3 acts as a protective or isolating device for the transistor Q3 by ^shunting any opposing current around the emitter-base diode emitter Basisdioöe äes transistor Q G® scarf · = tet, sRA around the transistor Qi against burn-through protection. "-

It should be remembered again that "the oscillator 2 works essentially the same as the Sehaltkreis or oscillator ± _$ , this oscillator i forming a switching device that is effective to supply an intermittent supply voltage or a pulsed supply voltage to the O-sail * lator 2 and let us now explain a typical "mode of operation of the device according to the invention"

The illustrated system operates as an "improved audible alarm system in which ready-made, integrable or integrated circuits are used to generate a pulsed or intermittent alarm signal for the security personnel. It is assumed that the supply voltage Bi is connected directly to the supply voltage terminal of the transistor Q3 ¹ is connected in the oscillator circuit 2, instead of the connection being made via the holding device i, as shown in the drawing. At the resonance frequency, the piezoelectric transducer Xl generates a relatively continuous noise or signals. render tone towards a continuous tone in certain ümweltbedingungen bevorzugt.Ei "method siness intermittent or pulsed tone at WaMIe? Xl za

produce,

109811 / ms.

et

generate * ^ consists in switching on an oscillator or a switching device between the supply voltage Bi and the supply voltage connection 4, the driver oscillator 2 to which the piezoelectric transducer Xl is assigned ο Di® Wsrt-Θ v © a Ri and Ci in the circuit 1! determine the flux Zsitkcmstante swr setting of the pulsation interval ö © s oscillator S ₀ Typical © values ssur generation of an acceptable pulsed tone at the piezoelectric transducer Xi slad Rl si OQO ^ and Ci s 60 λΡ, with reference to the basic structure of the oscillators It can be seen that in the 2 © itperioda ₉ in the famBsist? Q3 is © conductive, voltage 'and Strofflj which are supplied to the Ossillator 2, cause this in the usual, known type worked During this time, a relatively continuous Sound produced by the piezoelectric transducer Xi. However, during the second period of the oscillator function of the circuit i, the transistor Q3 is off and therefore none Voltage and no current fed to oscillator 2 “The oscillator 2 is not effective and, in fact, because there is no supply voltage and the piezoelectric transducer Xl does not emit a sound. As a result, an intermittent or pulsed sound is generated by the piezoelectric transducer Xl as desired.

Obviously, numerous modifications and changes can be made which are within the scope of the invention lie. :

Claims

10 9 811/12 7 6

Claims (10)

Claims l, j In the form of an integrated circuit buildable oscillator for operating an acoustic resonance converter, characterized by a first and a second transistor, each of which has an emitter, a base and a collector, these transistors being connected in cascade, a switching device which has an input and an output, the output of which is connected to the collector of the second transistor and wherein the input of the switching device can be connected to a voltage source, such that when the acoustic resonance transducer is connected to the collector of the second transistor and to the base of the connected to the first transistor, a signal supplied to the input of the switching means by the voltage source causes the oscillator to oscillate intermittently, thereby enabling the acoustic resonance transducer to generate an intermittent acoustic signal. 2. oscillator according to claim 1, characterized in that the switching device a second in the form of an integrated Has circuit buildable oscillator which has essentially the same structure as the first oscillator. 3. Oscillator according to claim 2, characterized in that this second oscillator has a resonant load between the input stage and the output stage of the second Oscillator is switched such that the second oscillator is periodically fed back according to the time constant of the resonance load. 109811/12 7 6 4. Acoustic alarm system, characterized by a first switching oscillator which is used with a resonant load j wherein a first and a second transistor are provided, each of which has an emitter, a base and a collector _t wherein the collector of the first transistor with the Base of the second transistor is connected and where a bias circuit is provided for the base of the first transistor and where © is provided in collector »load resistance for this first transistor and with a collector load circuit for the second transistor, where this © load circuit is a transistor and a bias circuit for the sen, which is constructed such that the transistor of the collector load circuit is non-conductive when the second transistor is conductive and vice versa and wherein a second oscillator can be built in the form of an integrated circuit is provided to operate an acoustic resonance transducer, this second Oscillation ator is constructed essentially the same as the first oscillator and wherein the emitter of the transistor in the load circuit of the first oscillator is connected to the collector of the transistor of the load balance in the second oscillator in such a way that when there are resonance loads between the emitters of the load transistors and the bases of the corresponding first transistors in each oscillator circuit are turned on, a signal fed to the collector of the load transistor in the first oscillator causes a pulsed or intermittent signal to be fed to the resonant load of the second oscillator, 5, alarm system naoh claim 4, characterized in that the second transistor in each oscillator circuit has one Diode is biased with one end of a corresponding one Diode in each of the oscillators is connected. 109811/127 6 ~ " 6. Alarm system according to claim 4, characterized in that the bias circuit for the base of the first transistor in each oscillator has a resistor connected between the base of the first transistor and the emitter electrode of the corresponding second transistor is switched on. 7. Alarm system according to claim 4, characterized in that a resistor is connected between the base and collector of the load transistor in each oscillator, that a diode between the emitter of the load transistor and the collector of the second transistor in each oscillator is on and that the base of the load transistor connected to the collector of the second transistor in each oscillator « 8. Alarm system according to claim 4, characterized in that a collector load resistance between the collector of the first transistor and the emitter of the LasttraRsistor in spring oscillator is switched on that a first Vorsgannurigsdiode between the base of the first transistor and the earth is turned on in every circuit and that a second bias diode between the emitter of the second transistor and the ground in each oscillator is on. 9. Alarm system according to claim 4, characterized in ₉ that a Resoaanzlast between 3em emitter of the load trans is sector and the base of the first transistor is switched on in each oscillator, 10. Alarm system according to claim 8 “characterized in that the resonance load In the second oscillator a piezoelectric one Crystal is. 109811/1276 Blank page