DE3029105A1 - Electronic and IR optical system for PCM transmission - has modulation stage with pulse shapers controlled by Schmitt trigger circuit and monostable stage - Google Patents

Abstract

The pulse modulated transmission system uses time multiplex transmission and infra-red radiation in a quasi optical arrangement. The arrangement has pulse modulated signals passed to a monostable timing stage for transformation into needle pulses and connected by a coaxial cable through a protective resistance to a Schmitt trigger stage for regenerating the pulse edges. This is followed by a delay stage and a pulse shaper operated by increasing edges of the pulses. The radiation system has e.g. three inputs, each with an input capacitor connected across it passing control pulses through a monitoring resistance to an infra-red diode. This is followed by two parallel branches each with a parallel capacitor and resistance, to a pair of switching transistors with a load switch on each base, forming pulse, driver stages. Connected to each input is a monitoring transistor stage with an AND-gate at the output.

Description

Radiator device

The invention relates to a radiator device, in particular for Generation and emission of short-term impulses in the infrared resp. visible light, to be used as a function-monitored simultaneous transmission device for a time-division multiplex signal transmission of a pulse-duration-modulated multi-channel system with pulse trains emitted from a modulation stage.

For the emission of lying in the optical or quasi-optical range Beams in free space for message transmission purposes are radiator devices required, taking into account the geometric configuration of the room is.

The invention is based on the object of a radiator device to create in such a way that an interference-free, low-noise, and shadow-free transmission as possible Reception is possible, with particular attention to optimal band utilization is to be taken, the set-up is simple and economical, an optimal operational safety can be guaranteed and an active function monitoring is provided.

This Aufgsbe is achieved according to the invention in that the in the Modulation stage generated, pulse duration modulated pulse trains - consisting of Signal pulses that are permanently modulated to a synchronization pulse and can be assigned to one channel each and interpulse periods of constant duration in between, where the Synchronization pulse is shorter than each signal pulse - for the purpose of transformation in Pulse phase modulated signals each with falling pulse edges a monostable Controlling the time stage, the formation of a time grid - consisting of needle pulses - Serve that these needle pulses via a coaxial line and a resistor, controlling a Schmitt trigger, one provided as a pulse shaper, with increasing Pulse edge triggered monostable multivibrator fed to the basic control of a Switching transistor are used that a constant current source to charge one against reference potential connected storage capacitor is used, the discharge of which via a monitoring series resistor, an infrared or light emitting diode series circuit and the collector-emitter path of the switching transistor takes place against reference potential, the charging current from the Constant current source corresponds to the continuous load capacity of the diodes. Is beneficial here the simple conversion of the pulse trains into a needle pulse raster, whereby the Modulation is only included in the spacing of the pulses from one another and depending on the transmitted Channel is erioiderable only an impulse. It is also advantageous that a synchronous Oscillator in the receiver is not required as there is also no fixed time grid gives.

This also results in more favorable noise ratios, since the Receiver occurring due to temporal inconsistencies (tremors) of the impulses Noise only due to the pulse position of two adjacent pulses to each other and not is given by the pulse position between signal and synchronization pulse, whereby signal pulses further away from the synchronization pulse result in a significant improvement in the Have noise ratios.

Needle pulses also offer a further advantage in that only a short high-energy impulse is emitted, and remains the same Transmitter energy, the range and the signal utilization ratio is increased. Opposite to conventional method results in the Advantage that the available stationary transmitter energy to a comparatively lower number of transmission pulses must be divided so that the individual impulse has a higher energy; To Another feature of the invention is provided as a pulse shaper, with rising edge triggered monostable multivibrator with multiple outputs, the basic control of several, each fed from a constant current source Storage capacitor-diode-Schalttransi stor circuits. This is advantageous here Control of several emitter chains with regard to radiation and independence of the emitter chains in front of each other with regard to operational safety.

As a further feature of the invention it is also provided that for active Function monitoring of one or more infrared or light-emitting diode series connection each to the capacitor-side connection of the monitoring series resistor Emitter and to the further connection of the monitoring series resistor via a Base resistance are connected to the base of a monitoring transistor and the Collector of the monitoring transistor over a bridged with a capacitor Voltage divider is connected to ground from two resistors, with each the divider points of the voltage divider directly or connected together via an AND element and via its output - via a function-indicating light emitting diode and a protective resistor are connected to reference potential, and that the voltage drop across the monitoring resistor leads to the switching on of the monitoring transistor only when pulsed current flows. Advantageous is here in the sense of operational safety the simple active monitoring of the emitter function.

According to an additional feature of the invention are between Schmitt triggers and pulse shaper a delay element and a branch at the coaxial line output for the connection of a further coaxial line and one used for the chain connection further radiator circuit provided, the delay element for delay compensation is used for transmitter synchronization, the input of the radiator circuit being high-resistance with respect to the characteristic impedance of the coaxial line, and where the free Branch at the end of a chain circuit with the characteristic impedance of the coaxial cable is completed. The interconnection of radiator devices is advantageous here to a simultaneous transmission device for a shadow-free transmission in large Rooms or rooms with special geometric relationships.

As an additional feature of the invention are to be mentioned that for The collector-emitter path of two switching transistors increases operational reliability via a parallel connection of a resistor and a capacitor for switching serve the infrared or light emitting diode series circuit, the control from Pulse shaper from each one power switching element on the bases of the switching transistors takes place that for directed radiation, in particular for reasons of security against eavesdropping, the transmission from a light emitting diode via fiber optic cable to the receivers takes place, wovet undr- and receiver-side low-attenuation coupling devices provided are that the power supply of the radiator circuit via the coaxial line can be done.

An exemplary embodiment of the invention is shown in the drawing and is described in more detail below.

1 shows the basic circuit diagram of the control part of a Radiation device according to the invention and FIG. 2 shows the detailed circuit diagram of a device according to the invention Beam device (to be controlled by a control part).

In Fig. 1, the control part of a radiator device is shown. The signal pulses from a modulation stage arrive at input E in the form of a pulse duration modulated pulse train and are each with falling pulse edge controlled in a monostable time stage Z into needle pulses and converted via a Coaxial cable route K via a series resistor R1 serving for protection purposes Schmitt trigger SCH is supplied to regenerate the edges and continues via a the delay element T to a pulse shaper IF, which is designed as a monostable multivibrator that can be triggered with a rising pulse edge, connected.

In the example according to the invention, the pulse shaper IF has three control outputs S1 ... S3 provided. The modulation stage is in an accessible central facility while the infrared heaters are attached to the ceiling, for example. A coaxial cable K is provided as the connecting element, with the coaxial line output a branch AB is provided for connecting or looping through further infrared radiators is, creating a simultaneous broadcast facility. To achieve synchronous transmission a delay element T is provided in each case, whereby one on the longest conduction path disabled coordination takes place and the signal propagation time in the coaxial lines to each other is customizable. Any open branch AB at the end of the chain must be connected to the shaft resistance complete. The proposed loop through via branch AB offers the advantage greater operational safety, as in the event of a heater failure (malfunction, partial power failure, etc.) other emitters remain functional. To reduce the cable routing, it is still advantageous to feed the radiators via the Make coaxial lines. In particular, here is on conservation aspects e.g.

to take historical halls into consideration, where aesthetic reasons forbid, To lay a bundle of cables.

The input to the further circuit is each very high-impedance opposite the coaxial line output.

In Fig. 2 the radiator device is without a control unit (see under Fig. 1) -shown. For reasons of operational safety, in the example according to the invention three heater parts are provided, which are monitored together.

The elements of the three similar radiator parts are indicated by the indices 1,2,3 differentiated, whereby the radiator parts with the index 2 or 3 only partially and are indicated by way of illustration. Based on Fig. 2, only the radiator part with the index 1 and the heater parts with the index 2 or 3 only partially considered. Three constant currents are independent of one another in a common power supply unit supply outputs are provided or there are three separate power supply units.

The constant currents are dependent on the continuous load capacity of the provided infrared diodes. A storage capacitor connected to ground Cli is connected to a constant current source N1 and via a monitoring series resistor Ril connected to a series circuit DS1 of 10 infrared diodes, the series circuit For reasons of operational safety, DS1 has two parallel circuits of one each Resistor R12, R12 'and a capacitor C12, C12' to the collector-emitter path ever a switching transistor T11, T11 'and further connected to ground. The intended Basic control of the switching transistors T11, part 'takes place from a control output S1 (Fig. 1) of the pulse shaper IF via a respective power switching element S1, S1.

In the example according to the invention there is a constant current of about 150 mA and a short-term pulse current for the emitted, triggered by needle pulses Infrared flashes of about 1.8 A are provided. Of the constant currents become the Storage capacitors CII, C21, C31 are charged, so that the energy for the flashes of light in the form of current pulses through the switching transistors T11, part 1, T21, T21 ', T31, T31 'can be obtained, with each individual transistor in the branch for the entire Switching capacity is designed. The short control pulse is generated in the pulse generator IF provided for the switching transistors T11, T11 ', T21, T21', T31, T31 'generated via the power switching elements provided as pulse driver stages, e.g. S1, S1 'the bases the switching transistors is supplied. Through the interaction of the constant current source e.g. N1 and storage capacitor e.g. CII becomes the diode series circuit e.g. DS1 when a switching transistor breaks, e.g. T11 or when a continuous control pulse is applied or if the control pulse frequency is too high in front of harmful overcurrents protected.

The connected to the storage capacitor CII and the diode series circuit DS1 upstream monitoring resistor R11 in the radiator section with index 1 is on the capacitor side with the emitter and on the diode series circuit side via one Base resistor P13 connected to the base of a monitoring transistor T12 and its collector via a voltage divider of two Resistances Ri4, R15 and connected in parallel to ground via a round capacitor C13, with the dividing point is connected to the first control input of a common AND element U. is, and wherein the second and third control input are each analogous to the radiator part is connected to the index 2 or 3. The output of the AND gate U is via a Light-emitting diode D and a series resistor RV connected to ground. In the monitoring resistors e.g. R11 causes a voltage drop in the described monitoring circuit when current flows after an integration of the voltage pulses and after an AND link for lights the light-emitting diode D indicates that all diode series circuits DS1, DS2, DSD of the radiator device function, which means that there is active control. By dimensioning the Switching elements, a pulse current of a specified level activates the circuit. In the event of a malfunction in the event of a power interruption or continuous current, the constant current source provided is limited to a small value, the light-emitting diode D does not light up. Likewise, the failure of only one diode series circuit e.g. DS1 or only one Diode already signaled as a fault, but the radiator device with reduced radiation output.

In the case of the radiator device according to the invention, the transmitted Information at the time interval between the short infrared light flashes, this information contains several voice Uiid or or data channels are.

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Claims (7)

Claims 16 Emitter device, in particular for generating and emission of short-term pulses in the infrared or visible range Light, for use as a function-monitored simultaneous transmission device for a Time-division multiplex signal transmission of a pulse-width modulated multi-channel system with pulse trains emitted from a modulation stage, d u r c h e k e n n -z e i c h n e t that the pulse duration modulated generated in the modulation stage Pulse trains - consisting of a synchronization pulse, duration modulated, one each Signal pulses that can be assigned to the channel and the duration of those in between constant pauses between pulses, the synchronization pulse being shorter than each signal pulse is - for the purpose of transformation into pulse-phase-modulated signals, each with falling Pulse edges controlling a monostable time stage, the formation of a time grid - Consisting of needle pulses - serve, ate these needle pulses via a coaxial line and a series resistor, controlling a Schmitt trigger, one as a pulse shaper provided monostable multivibrator triggered with rising pulse edge the base control of a switching transistor are used that a constant current source is used to charge a storage capacitor connected to reference potential, its discharge via a monitoring series resistor, an infrared or. Light-emitting diode series connection and the collector-emitter path of the switching transistor is against reference potential, the charging current from the constant current source being the continuous load capacity of the diodes is equivalent to. 2. Radiator device according to claim 1, d a d u r c h g e k e n n it is clear that the one provided as a pulse shaper triggered with a rising edge monostable Provided multivibrator with several outputs, the basic control of a corresponding number of storage capacitor-diode-switching transistor circuits, each fed from a constant current source serves. 3. Radiator device according to claim 1 or 2, d a -d u r c h g e it is not indicated that the active function monitoring of one or more Infrared or Light-emitting diode series circuits each on the capacitor side Connection of the monitoring resistor of the emitter and to the other connection of the monitoring series resistor via a base resistor, the base of a monitoring transistor are connected and the collector of the monitoring transistor via a with a capacitor bridged voltage divider consisting of two resistors to ground is switched, with the divider points of the voltage divider directly - or interconnected via an AND element and via its output - via a function-indicating one Light-emitting diode and a protective resistor are connected to reference potential, and that the Voltage drop at the monitoring series resistor only with pulse current flow for switching on of the monitoring transistor leads. 4. Radiator device according to claim 1 to 3, d a -d u r c h -g e k e n-n z e i c h n e t that there is a delay element between the Schmitt trigger and the pulse shaper and a branch at the coaxial line output for connecting one of the chain circuits Serving further coaxial line together with a further radiator circuit is provided are, the delay element for delay compensation for transmitter synchronization serves that the input of the radiator circuit has a high resistance to the characteristic impedance the coaxial line is, and that the free branch from Ab at the end of a chain circuit with the characteristic impedance of the coaxial cable is completed. 5. Radiator device according to claim 1 to 4, d a -d u r c h g e It is not stated that the collector-emitter path is used to increase operational reliability two switching transistors each via a parallel connection of a resistor and a capacitor for switching the infrared or light-emitting diode series circuit serve, with the control from the pulse shaper via one power switching element each takes place via the bases of the switching transistors. 6. Radiator device according to one of the preceding claims, d a d u r c h g e k e n n n z e i c h n e t that for directed radiation, in particular for reasons of security against eavesdropping, the transmission is carried out by a light-emitting diode Fiber optic cable to the receivers takes place, with low attenuation on the transmitter and receiver side Coupling devices are provided. 7. Radiator device according to one of the preceding claims, d a d u r c h e k e n n n z e i c h n e t that the power supply of the radiator circuit takes place via the coaxial line.