NO743872L - - Google Patents

Description

Information transmission facility.

The invention relates to an information transmission system£ for wireless transmission, comprising an interrogation station which emits a high-frequency signal as an interrogation signal, and a sewing station which receives the interrogation signal and sends out again a modified high-frequency signal containing the information to be transmitted, to the interrogation. the station where it is detected.

Such a facility can e.g. is used for railway wagon identification where the inquiry station is fixed and the reply station is placed on the wagons to be identified, and thus are movable past the inquiry station. The answering station should be passive, so that

no energy needs to be supplied for its function. The answering station does not need to be reprogrammable.

In another design, the facility can be used to provide

traffic information to drivers of trains or motor vehicles, as the questioning station is placed on a moving vehicle and the answering station is fixed. In this case too, it is desirable to have one. passive answering station. In this case, the answering station may possibly be reprogrammable, e.g. to specify a maximum speed that varies depending on the weather, snow, etc. With the requirement for reprogrammability, it may be necessary that there is an energy source in the answering station, e.g., in the form of a small battery or can be connected to an external energy source during the actual reprogramming.

With a known device of this kind, an interrogation signal is emitted whose frequency changes linearly with time, and which thus contains a number of different frequencies during each frequency sweep. The answering station consists of a number of hollow resonators which are tuned to specific interrogation signal frequencies, which hollow resonators pass through these frequencies to an antenna for retransmission to the interrogation station. The way it works is. i.e. so that only the energy

at the frequencies that correspond to the frequencies of the cavity resonators send" out again, while all the other frequencies are consumed in the answering station. The information lies in which frequencies are sent out again....

Such an answering station is completely passive and robust in its structure, but the system as a whole becomes relatively complicated and expensive as a result of the varying frequencies on the transmitting side and the answering stations' structure in the form of a combination of a large number of carefully tuned cavity resonators determined for each answering station . Furthermore, it cannot be avoided that the emitted energy is reflected towards targets in the vicinity of the answering station, which can make it difficult to detect the answering code, and the efficiency, i.e. the ratio between re-sent and emitted energy, is very small. The answering station in the known device is not reprogrammable as it must be replaced in its entirety to change the answer code.

Sending out a continuous or pulsed single-frequency signal is also known as a polling signal. In all known systems of this kind, there is at least one oscillator at the answering station. The oscillator is used to separate the frequencies of the answer signals from the question. the repetition frequency. The oscillator can also be used to transmit a coded message. Then the code is made up of the response signal energy. at the different frequencies, like the response signals from the above-described response stations with cavity resonators.

The purpose of the invention is for a plant with out- sending a single-frequency signal as a query signal to eliminate the need for an oscillator in the answering station at the same time that the answering station is completely passive in that there is no need for any external power source and the amount of information that is transmitted can be made unlimited within the framework of the available transmission time.

The characteristic feature of the invention is that when sending a continuous or pulsed single-frequency signal as a questioning signal, the answering station comprises a non-linear element which is fed to the signals sent from the questioning station and received in the answering station of the selected frequency, and from which min€'" |n harmonic is derived and fed back directly as a response frequency to the interrogation station after modulation in a modulator that is controlled by an active code unit in such a way that the retransmitted response signal has the form of a modulated pulse train, as the drive voltage for the code unit is obtained in the opposite direction of the interrogation signal, so that part of the interrogation signal's energy is used for operation of the code unit with the following modulator and another part is used for direct retransmission in pulse-modulated form after passive frequency transformation in the dfet unlinearizing element.,

The invention thus achieves the necessary separation between the frequency of the inquiry signal and the frequency of the response signal by passive frequency transformation, e.g. frequency doubling, in a non-linear element. The coded message is not transmitted using a frequency code. Instead, the coding in the time plane takes place in such a way that the retransmitted response signal after the frequency transformation, e.g.

to twice the interrogation signal frequency, is modulated e.g. be blocked or let through in accordance with the code. The energy to drive the encoder is obtained by rectifying part of the interrogation signal. Energy.

As the coding takes place in the time plane, a time control input is required to determine the output rate of the code. In a preferred embodiment, the interrogation signal is pulsed and the time signals to the code unit are obtained by detecting the interrogation signal. The time control unit can also be placed in the answering station, e.g. when the interrogation signals are continuous. In this case, an oscillator is introduced into the answering station. This shall not cause a frequency separation between the inquiry signal and the response signal or determine the frequency separation in a frequency code, which would entail accuracy requirements for frequency security.

The principle of the invention involves a division of the energy in the interrogation signal into two parts, a séaf which is sent back directly to the interrogation station after passive frequency transformation in the non-linear element and another part which is rectified to provide control voltages to the code unit, can be illustrated with the following example: If .the nonlinear element consists of a square element where the current i is proportional to the square of the voltage V

i« const tvV2.. where it. quadratic element is fed with a signal V = A sine ta t,

where A st is the amplitude, cd «r the angular frequency and t «3* the time

the electricity:

The current contains a direct current component, which can be used as

drive energy and a component whose frequency is twice the input signal frequency. By designing the non-linear element and associated \filter circuits in a suitable way, in principle any harmonic can be filtered out and used as a carrier frequency for the retransmission.

The invention will be explained in more detail below with reference to the drawing. Fig. 1 shows a block scheme for an information transmission system according to the invention* Fig. 2 shows a block core for the answering station.

The inquiry station 10 in fig. 1 comprises a microwave generator 11 with subsequent pulse modulator 12. The generator 10 continuously supplies a carrier frequency .f which is pulse modulated in the modulator 12 with a pulse modulation frequency f^. Alternatively, a pulsed microwave generator can be used. The pulsed microwave signal is sent out through an antenna 13. When an answering station 1*1 comes within the range of the transmitted signals, the signals are received by a receiving antenna 15. : After processing in the answering station, a modified microwave signal is re-transmitted from the answering station through the antenna 16. The antennas 15 and 16 may in practice be two microwave ports which are connected by

.an external common antenna. The retransmitted signals are also pulsed. but in the retransmitted pulse train the pulses appear in accordance with a

given code that contains the information. They rebroadcast Signals

has a carrier frequency which is a harmonic of the transmitted interrogation frequency, e.g. the second harmonic. The signals are decoded and the information judged in a decoding unit 17, which in the 3in input has a filter 18 tuned to the selected harmonic. ..Fig*1 also shows the curves for the interrogation signal and the response signal with the double frequency.. .Fig. 2 shows an answering station with a receiver antenna 15 which is connected to a non-linear element 20, which is fed to the received signals. With the output from the element 20, the preband is a first filter 21 and a second filter 22. The first filter 21 has a large time constant and emits a DC voltage which is supplied as drive voltage to the eh code unit 23. The second filter 22 is tuned to the double one. transmitted carrier frequency and emits an output signal to a modulator 24. On a control input, the modulator receives control pulses from the code unit 23 in accordance with a program storage device in: the code unit. The time pulse information for the code unit can be taken out

the incoming pulse signals and the code unit can possibly have a control input for this purpose which receives the incoming signals before they are filtered. For each received pulse, the code unit eh generates control pulses for the modulator or not in accordance with the given code calculated from a starting moment. The modulator is in principle an electronic switch, which lets through or blocks the microwave pulses from the filter 22. The pulses that are let through the modulator are sent out again through the antenna, 16. So that the time information is not lost and/or the energy transfer for the control of the answering station's code unit is not. must be reduced by breaking or damping as the non-linear element's current path, the switch can break the supply of the microwave pulses to the answering station's antenna by fully or partially absorbing these in an energy-consuming circuit, e.g. in case of significantly reduced goodness in the filter 22.

The code unit begins to work and emit control pulses to the modulator 24 as soon as a sufficiently large driving voltage has been received from the filter 21. It is appropriate that the transmission begins with a start code that determines the start moment.t before the transmission of the relevant response code. After each sending of the reply* code, a new start code with a subsequent reply code may be sent after a short delay, which is repeated as long as the answering station receives the inquiry signal. The non-linear element can be a diode. The IC unit is preferably built up of MOS circuits in integrated form which have low current consumption, so that in the described manner it is possible to utilize the received energy both to drive the coding unit and to reproduce part of the energy as a response signal. double frequency. The structure of the code unit, like the other components, is known in and of itself and shall not be described in more detail here.

Instead of sending out a pulsed interrogation signal from the polling station, it is also possible to send out a continuous microwave signal as a polling signal. The answering station must then itself contain a time management device for the code unit, which complicates the answering station somewhat and increases the need for drive energy. It is also not necessary to use the second harmonic as the carrier frequency for the response signal, but in principle any harmonic. The filter 22 in the answering station can also be bypassed. Furthermore, instead of a common diode, two separate diodes can be used, one for providing the harmonic and one for providing the rectified voltage that is used as drive voltage in the answering station. In principle, any modulation of the response pulses can also be used, which makes it possible to distinguish binary characters. Preferably, amplitude modulation is used so that one binary character, as in the example shown, can have the same shape as the interrogation pulses (unmodulated pulse), while the other binary element has a different amplitude characteristic, e.g. by that one

part of the response pulse is more or less attenuated with regard to amplitude time in relation to the other parts.

In the description above, it is stated that the system works with frequencies in the microwave range. - Since the limits of the microwave range are not well defined and since the principle of the information transmission system can be used within frequency ranges that are close to the microwave range, such frequencies can also be used according to the invention . The applicable frequency range is naturally limited by the fact that the information transmission must take place wirelessly using radiation.

Claims (6)

1. Information transmission system for wireless transmission, comprising an interrogator station (10) which emits a high-frequency signal as an interrogation signal, and a response station (14) which receives the interrogation signal and sends out again a modified high-frequency signal containing the information to be transmitted, to the interrogation station where it is detected , in that the interrogation signal is a continuous or pulse-shaped single-frequency signal. and the response signal has a frequency that is a harmonic of the interrogation signal's frequency and the interrogation station's receiver are matched to this harmonic, characterized by that. the answering station (14) comprises a non-linear element (20) which is fed to the from the interrogating station i10) transmitted, and in the answering station (14) received signals of the selected frequency, and from which at least one harmonic is derived and fed directly back as the answering frequency to the interrogating station after modulation in a modulator (24) which is controlled by an active coding unit (23) in such a way that the retransmitted response signal has. form of a modulated pulse train, the drive voltage for the code unit (23) being obtained by rectification of the interrogation signal, so that part of the interrogation signal's energy is used for operation of the code unit with the following modulator and another part are used for direct retransmission in pulse code modulated form after passive frequency transformation in the non-linear element.(20). 2. Installation according to claim 1, characterized in that the non-linear element (20) comprises a diode with mainly square characteristics. 3. Installation according to claim 1 or 2, characterized in that both the rectified voltage for operation of code- the unit (23) with the modulator (24) as the selected harmonic which is sent, back as the response frequency, is derived from one and the same non-linear element (20). 4. Installation according to one of the requirements 1-3" characteristics served by the fact that the code unit (23) is designed as a logic unit which, depending on supplied control information, emits binary control pulses see, e.g. voltage or no voltage, to the modulator (24), which control pulses appear in accordance with a given time code containing the information.' 5.. Installation according to one of claims 1-4, characterized in that the modulator (24) is arranged to regulate the transmitted signal's amplitude as a function of the amplitude of the control voltage of the modulator. 6. Plant according to one of claims 1-5, where the interrogation signal is pulsed, characterized in that the modulator (24) is arranged to, in accordance with the applied control signal, produce a pulse train in which the one binary character element is represented by a response pulse that is equal to the frequency-transformed part of the interrogation pulse in modulated form, while the other binary sign element is represented by a completely or partially suppressed pulse. 7*- Installation according to one of claims 1-6, grade i-, ensures that the modulation of the response signal takes place after the nonlinear element, by changing the connection to the antenna so that the response signal is attenuated completely during time intervals determined by the code in the l;od code unit, and so that incoming inquiry signals to the non-linear element and the voltage derived therefrom for operation of the code unit are mainly not affected.