FR2612714A1 - System for transmitting a low-frequency signal - Google Patents

Abstract

The present invention relates to a system for remote transmission and audible broadcasting of a low-frequency signal, in particular for sound rigging of chair lifts and cable cars. The system comprises a transmitter which includes an input modulator stage operating by pulse-width modulation which generates an auxiliary signal consisting of a succession of square-pulses whose width is proportional to the amplitude of the low-frequency signal, an output modulator stage which effects an all-or-nothing amplitude modulation of the HF carrier wave in tempo with the auxiliary signal and at least one receiver tuned to the frequency of the carrier wave. The receiver comprises a detector stage 40 which effects an envelope detection and an output amplifier stage 44 of the push-pull type. According to the invention, the output amplifier stage 44 is off and consumes no current in the absence of reception. The receiver has only a very low consumption in the absence of reception and has no On/Off switch or volume control.

Description

 The present invention relates to the field of remote transmission and broadcasting of a low frequency signal.

 The main object of the invention is to provide simple, economical and robust means for transmitting a low frequency signal remotely and for broadcasting this signal, audibly, at a plurality of receivers.

 An auxiliary object of the invention is to propose a transmission system which does not require gain adjustment at the level of the receivers.

 Another object of the present invention is to propose a system which does not require an intervention of commissioning / decommissioning at the level of the receivers.

 The present invention finds very particularly, but not exclusively, application for the sound system of chairlifts and cable cars. In the context of this application, the system in accordance with the present invention makes it possible to establish communication with travelers trapped in the cabins in the event of an accident or incident. The system according to the invention therefore makes it possible to transmit reassuring instructions or messages to travelers, for example by indicating to them the duration of immobilization. The system according to the present invention thus makes it possible to calm the anxiety created in certain people by the isolation due to the temporary immobilization of chairlifts or gondolas. Furthermore, in normal service of chairlifts or gondolas, the transmission and transmission system sound system according to the present invention can be used to broadcast music and advertising messages.

 However, as indicated above, the present invention is not limited to the sound system of chair lifts or cable cars. The transmission system according to the invention can for example be used to broadcast, in bus shelters, audio, musical, advertising, information messages, or even local radio broadcasts.

The aforementioned aims are achieved, within the framework of the present invention, by means of a low frequency signal transmission system comprising - a transmitter which
an input modulator stage working-by
pulse width modulation, which generates
an auxiliary signal consisting of a series of
slots whose width is proportional to
the amplitude of the low frequency signal,
an output modulator stage which receives the if
general auxiliary and a HF carrier wave and operates
an all-or-nothing amplitude modulation of the wave
HF carrier at the rate of the auxiliary signal, and - at least one receiver tuned to the frequency of the carrier wave and comprising a detector stage which operates envelope detection to isolate the auxiliary signal.

 According to an advantageous characteristic of the invention, each receiver comprises an output amplifier stage of the push-pull type which drives a loudspeaker.

 According to a characteristic currently considered preferential, the output amplifier stage of the push-pull type is charged by a branch comprising in series a loudspeaker and a capacitor, while the amplifier stage of the push-pull type comprises two transistors d symmetrical attack whose common emitter or collector is connected to the midpoint of the charging branch of this stage.

 As will be explained below, this characteristic makes it possible to limit the consumption at rest of the receiver.

 More precisely still, preferably, the loudspeaker is connected to the common emitter or collector of the symmetrical output transistors of the amplifier stage of the push-pull type.

 According to another advantageous characteristic of the invention, each receiver comprises a pre-amplifier stage which receives the auxiliary signal from the detector stage, pre-amplifier stage comprising two cascaded transistors, respectively upstream and downstream, the emitter of the transistor downstream being connected to the base of the upstream transmitter by a feedback resistance.

 The structure of such a preamplifier stage makes it possible to obtain good stability in direct current, while having a maximum gain in alternating current.

 According to another advantageous characteristic of the invention, the input adulator stage of the transmitter comprises a time base which generates a timing signal at a fixed frequency, and a monostable triggered by the timing signal and whose slot width output is proportional to the level of the low frequency signal it receives as input.

 Preferably, according to the present invention, the detector stage of each receiver comprises a Schottky-type diode.

 The present invention also relates to the transmitter and receiver making up the aforementioned system.

 Preferably, each receiver is powered by an accumulator, for example of the cadmium-nickel type, charged by a photovoltaic pay panel.

 Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings given by way of nonlimiting example and in which - FIG. 1 represents a schematic view, in the form of functional blocks, of a transmitter according to the present invention, - Figure 2 illustrates in the form of a timing diagram of the electrical signals sampled at different points of the transmitter illustrated in Figure 1, and - Figure 3 schematically illustrates the structure of a receiver according to the present invention.

 We will first describe the structure of the transmitter 10 illustrated diagrammatically in FIG. 1.

 In FIG. 1, the input of the transmitter 10 which receives the low frequency signal to be transmitted is referenced 12. The output antenna is referenced 14.

 As indicated above, for the most part, the transmitter 10 comprises an input modulator stage working by pulse width modulation and an output modulator stage which operates by all-or-nothing amplitude modulation.

 More specifically, according to the embodiment illustrated in Figure 1 attached, the transmitter 10 comprises a monostable 16, a time base 18, an amplifier module 20, an output modulator stage 22, a low-pass filter 24 and a comparator 26.

 The input modulator stage working by pulse width modulation consists of the monostable 16.

 The time base 18 generates a timing signal at a fixed frequency. The timing signal is illustrated diagrammatically on the last line of FIG. 2.

 The timing signal generated by the time base 18 is applied to the trigger input of the monostable 16. As a result, the monostable 16 generates fixed frequency output slots. The output signal of the monostable 16 is illustrated diagrammatically on the second line of FIG. 2.

 Furthermore, the width of the slots managed by the monostable 16 is modulated by the amplitude of the low frequency signal that the latter receives at input.

 The low frequency signal applied to the input 12 of the transmitter 10 is illustrated diagrammatically on the first line of FIG. 2.

 As illustrated schematically in this FIG. 2, the width 1 of the slots generated at the output of the monostable 16 is therefore linked to the instantaneous amplitude E of the low frequency signal.

 Preferably, the frequency of the timing signal generated by the time base 18 is at least twice the upper frequency of the low frequency signal to be transmitted.

 Those skilled in the art know many types of monostables capable of being triggered by a timing signal and adapted to generate slots at the output, the width of which is modulated by the amplitude of a control signal applied at the input. Therefore the structure of the monostable 16 will not be described in more detail below.

 Preferably, to ensure a low distortion of the information, the width modulation signal applied to the input of the monostable 16 is formed by comparison, in element 26, of the low frequency signal applied to the input 12, of on the one hand, and of the signal obtained at the output of the monostable 16 after passing through a low-pass filter 23, on the other hand. This feedback arrangement is conventional in itself and will not be described in more detail below.

The series of width-modulated slots obtained at the output of the monostable 16 will hereinafter be referred to as "auxiliary signal
This auxiliary signal is preferably applied to an amplifier module 20 and from there to an output modulator stage 22. The output modulator stage 22 also receives an HF carrier wave generated by a module 28. The HF carrier wave can be for example in the 100 MHz band.

 The output modulator stage 22 which receives the auxiliary signal and the HF carrier wave operates an all-or-nothing amplitude modulation of the HF carrier wave at the rate of the auxiliary signal.

 The modulated signal obtained at the output of stage 22 is illustrated diagrammatically in the third line of FIG. 2.

 This signal is applied to the antenna 14. This antenna can be directive in the axis of the line of chairlifts or gondolas.

 We will describe the structure of the receiver 30 illustrated in Figure 3 attached to equip each chairlift or gondola.

 Each receiver 30 preferably comprises a power supply module 36, an input stage 38, a detector stage 40, a pre-amplifier stage 42, an output amplifier stage 44 of the push-pull type and a loudspeaker 46.

 Preferably, each receiver 30 is powered by an Acc accumulator, such as a cadmium-nickel accumulator, charged by a photovoltaic solar panel 32.

 The Acc battery can be made up of two cadmium-nickel cells connected in series to deliver a total supply voltage of 2.4 V.

 The solar panel 32 intended to keep the Acc accumulator in charge is preferably placed flat on the roof of the cabins of cable cars.

 The input stage 38 of the receiver 30 comprises an antenna 34, two windings L1, L2 and an adjustable capacitor C1.

The antenna 34 is connected via the winding L1 to the ground of the assembly. The coil L1 is coupled to the second coil L2. The adjustable capacitor
C1 is connected in parallel with the second winding L2.

The parallel cell including the adjustable capacitor
C1 and the coil L2 form a resonant circuit tuned to the frequency of the HF carrier wave.

A first point common to the adjustable capacitor
C1 and to the winding L2 is connected to the assembly ground.

The second point common to the adjustable capacitor C1 and to the winding L2 attacks the detector stage 40.

 The detector stage 40 operates an envelope detection on the signal received on the antenna 34 and present at the second aforementioned second point common to the adjustable capacitor C1 and to the coil L2. In other words, the aim of the detector stage 40 is, conventionally in itself, to eliminate the HF carrier wave in order to recover the auxiliary signal corresponding to the series of slots modulated in width generated by the monostable 16.

The detector module 40 includes a diode
D1, a resistor R1 and a capacitor C2.

 The second aforementioned second point common to the variable capacitor C1 and to the coil L2 is connected to the positive supply terminal + Vcc of the accumulator Acc via the resistor R1 and the diode D1.

 A first terminal of the resistor R1 is connected to the positive supply terminal + Vcc. The second terminal of the resistor R1 is connected to the anode of the diode D1.

The cathode of the diode D1, which constitutes the input of the detector stage 40, is connected to the aforementioned second point common to the adjustable capacitor C1 and to the winding
L2. The anode of diode D1 is connected to the ground of the assembly via a capacitor C2.

 The point common to the anode of the diode D1 and to the capacitor C2 constitutes the output of the detector stage 40.

 The signal present on the output of the detector stage 40 is similar to the aforementioned auxiliary signal composed of a series of slots modulated in width, however insofar as the diode D1 operates a negative detection, the signal present on the output of the detector stage 40 is inverted with respect to the auxiliary signal.

 The detector stage 40 is connected to the preamplifier stage 42 by means of a connection capacitor C3.

The preamplifier stage 42 includes two transistors T1, T2 of the NPN type, three polarization resistors
R2, R3 and R4, a feedback resistor R5 and a capacitor C4.

 The connection capacitor C3 connects the anode of the diode D1 to the base of the upstream transistor T1. This is mounted as a common transmitter, its transmitter is therefore connected to the assembly ground.

 The collector of transistor T1 is connected to the positive supply terminal + Vcc via a bias resistor R2. The collector of the upstream transistor T1 is also connected to the base of the downstream transistor T2.

 The collector of the downstream transistor T2 is connected to the positive supply terminal + Vcc via a bias resistor R3.

The emitter of the downstream transistor T2 is connected to the ground of the assembly by means of a cell comprising in parallel the bias resistor.
R4 and the capacitor C4.

 In a conventional manner in itself, the resistor R4 serves as a series feedback in intensity. It is alternately decoupled by capacitor C4.

 Finally, according to an important characteristic of the invention, the feedback resistance R5 connects the base of the upstream transistor T1 to the emitter of the downstream transistor T2.

 The resistor R5 makes it possible to simultaneously obtain good stability of the pre-amplifier stage 42 continuously, and a maximum amplification gain in alternation.

 The pre-amplifier stage 42 is connected to the output amplifier stage 44 by means of a link capacitor C5.

The output amplifier stage 44 is of the push-pull type. It includes four transistors T3, T4, T5,
T6 and a bias resistor R6. The amplifier stage 44 more precisely still comprises two symmetrical driving transistors T3, Tq, respectively of PNP and NPN type, and two symmetrical output transistors T5, T6, respectively of PNP and NPN type.

 The bases of the driving transistor T3, T4 are interconnected. The connecting capacitor C5 connects the collector of the transistor T2 which constitutes the output of the preamplifier stage 42, at the base of the drive transistors T3, T4 of the amplifier stage 44.

 Furthermore, the base of the transistors T31 T4 is connected to the positive supply terminal + Vcc via the bias resistor R6.

 The emitters of the transistors T3, T4 are interconnected.

 The collector of the driving transistor NPN T4 is connected to the base of the output transistor PNP T5. The emitter of the output transistor T5 is connected to the positive supply terminal + Vcc.

The PNP drive transistor T3 collector is connected to the base of the NPN T6 output transistor. The emitter of transistor T6 is connected to the ground of the assembly. Furthermore, the collectors of the output transistors T5,
T6 are interconnected. They constitute the output of the amplifier stage 44.

This output of the amplifier stage 44 is charged, via a filter, by a charging branch comprising in series a loudspeaker 46 and a capacitor C6. The above filter includes a coil
L3 and a capacitor C7.

 The coil L3 is connected between the output of the amplifier stage 44 (common collector of the output transistors T5, T6) and a first terminal of the loudspeaker 46.

 The second terminal of the loudspeaker 46 is connected to the ground of the assembly by means of the abovementioned capacitor C6.

 The capacitor C7 of the filter is connected between the point common to the coil L3 and to the speaker 46 and the earth of the assembly.

Finally, according to an important characteristic of the invention, the point common to the emitters of the driving transistors T3, T4 is connected via a resistor R7, to the midpoint of the load branch of the amplifier stage 44 In other words, the point common to the emitters of driver transistors
T3, T4 is connected via the resistor
R7 in common with loudspeaker 46 and capacitor C6.

 In the absence of an alternating signal on the input of the amplifier stage 44 (absence of reception on the antenna 34) the terminal of the output capacitor C6 common to the loudspeaker 46 rises to the positive supply potential + Vcc, or 2.4 V in the case of the use of an Acc accumulator composed of two cadmium-nickel cells.

 Therefore, in the absence of reception on the antenna 34, the pushpull type output amplifier 44 consumes no current.

Note also that in the absence of reception on the antenna 34 the consumption of the pre-amplifier stage 42 is negligible. This consumption corresponds to the bias current determined by the resistors
R2, R3 and R4. In summary, the operation of the receiver 30 is as follows. The signal transmitted by the transmitting antenna 14 and received on the antenna 34 is filtered by the oscillating circuit C1-L2. The signal obtained at the output of this oscillating circuit corresponds to a HF carrier wave of fixed frequency modulated in amplitude all or nothing at the rate of an auxiliary signal consisting of a series of slots whose width is proportional to the instantaneous amplitude of a low frequency signal. The detector stage 40 eliminates the HF carrier wave and separates the aforementioned auxiliary signal. This auxiliary signal is amplified and clipped first in the preamplifier stage 42 of high gain then in the output stage 44 of the push-type pull to be applied to the output speaker 46. It will be noted that advantageously, the information to be transmitted, which corresponds to the low frequency input signal is defined by the width of the slots making up the auxiliary signal recovered at the output of the detector stage 40. Furthermore, the gain of the preamplifier stage 42 is high enough to clip the signal. Thus, the system is independent of the signal level received on the receiver and the output level is independent of the distance between the transmitter and the receiver.

 In other words, thanks to the structure proposed in the context of the present invention, no gain adjustment is necessary at the receiver. In addition, no commissioning intervention at the start of the day and decommissioning at the end of the day is necessary at the receivers.

Indeed, as indicated previously, when the emission is interrupted, the capacitor C6 blocks the push-pull amplifier stage s4 of output and interrupts any consumption thereof while the polarization resistors R2, R3 and R4 define a current bias of the transistors T1, T2 quite negligible. Thus, the consumption of the receiver 30 outside of the transmission periods is entirely negligible. This is a very important feature of the invention. The Applicant has found that the need for daily manual intervention to start and stop each receiver (which will most often be at least at least a hundred on the chairlift or cable car chains) as well as the possible periodic change of batteries would be prohibitive for the operation of a system for the transmission of information in the context of chairlifts or cable cars.

 According to an embodiment which has given satisfaction, but indicated by way of nonlimiting example - the component R1 has a resistance of 100 kQ, - the diode D1 is of the BAT 85 type, - the capacitor C2 has a capacity of 3 pF , - the link capacitor C3 has a capacity of 0.1 F, - the component R2 has a resistance of 47 kn, - the component R3 has a resistance of 6.5 kQ, - the component R4 has a resistance of 4, 7 kQ, - component R5 has a resistance of 270 KQ, - capacitor C4 has a capacity of 0.1 F, - connection capacitor C5 has a capacity of 0.1 ssF, - component R6 has a resistance of 470 KQ, - the output capacitor C6 has a capacity of 100 #F, - the R7 component has a resistance of 100 Q.

 Of course the present invention is not limited to the embodiment which has just been described but extends to all variants in accordance with its spirit.

Claims (13)

 1. A system for transmitting a low frequency signal, in particular for the sound system of chairlifts or cable cars, characterized in that it comprises - a transmitter (10) comprising  an input modulator stage (16) working by  pulse width modulation, which generates a  auxiliary signal consisting of a series of slots  whose width is proportional to the amplitude  low frequency signal,  an output modulator stage (22) which receives the  auxiliary signal and a carrier wave (HF) and operates  an all or nothing amplitude modulation of the wave  carrier (HF) at the rate of the auxiliary signal, and - at least one receiver (30) tuned to the frequency of the carrier wave and comprising a detector stage (40) which operates envelope detection to isolate the auxiliary signal.  2. Transmission system according to claim 1, characterized in that each receiver (30) comprises an output amplifier stage (44) of the pushpull type which drives a loudspeaker (46).  3. Transmission system according to claim 2, characterized in that the output amplifier stage (44) of the push-pull type is charged by a branch comprising in series a loudspeaker (46) and a capacitor (C6) and that the push-pull amplifier stage (44) comprises two symmetrical drive transistors (T3, T4) whose common emitter or collector is connected to the midpoint of the charge branch of this stage (46, C6 ).  4. Transmission system according to claim 3, characterized in that the loudspeaker (46) is connected to the common transmitter or collector of the symmetrical output transistors (T5, T6) of the push-type amplifier stage. pull (44) via a filter.  5. Transmission system according to one of claims 1 to 4, characterized in that each receiver (30) comprises a pre-amplifier stage (42) which receives the auxiliary signal from the detector stage (40), l pre-amplifier stage comprising two cascade transistors (T1, T2) respectively upstream and downstream, the emitter of the downstream transistor (T2) being connected to the base of the upstream emitter (T1) by a feedback resistance ( R5).  6. Transmission system according to one of claims 1 to 5, characterized in that the input modulator stage (16) of the transmitter (10) comprises a time base (18) which generates a signal fixed frequency timing, a monostable (16) triggered by the timing signal and whose width of output slots is proportional to the level of the low frequency signal it receives as input.  7. Transmission system according to one of claims 1 to 6, characterized in that the detector stage (40) of each receiver (30) comprises a diode (D1) of Schottky type.  8. Transmitter as defined in one of claims 1 to 7.  9. Receiver for broadcasting a low frequency signal characterized in that it comprises - an input stage (38) tuned to a specific carrier frequency, - a detector stage (40) which operates envelope detection and - an output amplifier stage (44) of the pushpull type charged by a branch comprising in series a loudspeaker (46) and a capacitor (C6), the amplifier stage of the push-pull type (44) comprising two transistors d 'symmetrical attack (T3, T4) whose common emitter or collector is connected to the midpoint of the load branch of this stage.  10. Receiver according to claim 9, characterized in that it comprises a pre-amplifier stage (42) which receives the signal from the detector stage (40), the pre-amplifier stage (42) comprising two transistors in cascade (T1, T2) respectively upstream and downstream, the emitter of the downstream transistor (T2) being connected to the base of the upstream emitter (T1) by a feedback resistance (R5).  11. Receiver according to one of claims 9 or 10, characterized in that the detector detector stage (40) comprises a diode (D1) of the Schottky type  12. Receiver according to one of claims 9 to 11, characterized in that the detector stage (40) comprises a diode (D1) whose cathode is connected to the input filter (L2, C1) of the receiver.  13. Receiver according to one of claims 9 to 11, characterized in that it is powered by an accumulator (Acc) 1 preferably of Cd-Ni type, charged by a photovoltaic solar panel (32).