Method of communicating information between a transmitter and a receiver using ultrawideband signals

Useful information taking the form of an analog or digital voltage is communicated between a transmitter and a receiver using UWB signals. The transmitter includes a subcarrier modulator, a high frequency oscillator and a transmission antenna and the receiver includes a reception antenna and an amplifier and a demodulator for discriminating the useful information in a signal received at the reception antenna. On transmission, the method generates a narrow frequency band high frequency carrier, modulates the high frequency carrier using a subcarrier with a modulation index at least equal to 10, and modulates the subcarrier using the useful information. On reception, the method demodulates the carrier to extract therefrom the subcarrier and demodulates the subcarrier to extract therefrom the useful information.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a method of establishing communications using ultrawideband (UWB) signals.

2. Description of the Prior Art

Wavelet signals are used in the communication art to transmit digital information using modulation, for example pulse position modulation (PPM) or ON-OFF keying (OOK) of the wavelet signals.

Because the energy spectrum of wavelet signals is spread over a very wide frequency band, the global energy level can, all other performance factors being equal, be relatively low, with the result that using wavelet signals makes it easier to conform to the regulations governing telecommunications. Moreover, communication using wavelet signals is relatively insensitive to interference and to reflections, and therefore can be used with advantage in confined environments in which other narrow frequency band high power communications are already present. As a general rule, a UWB signal has a bandwidth BRF such that, at a center frequency fc:

Several methods of generating UWB wavelet signals are known in the art. They employ either short Gaussian pulses or bursts or scanning of sinusoidal signals obtained by radio techniques or fast switching (fast on-off keying) techniques.

However, as the duty factor of wavelet signals used for digital communications is relatively low, the prior art methods cited above have the drawback of necessitating synchronization between the transmitter and the receiver, to make the active window of the receiver coincide with wavelets sent by the transmitter. This kind of synchronization requires relatively complex circuits. Moreover, the circuits necessary for generating the wavelets are also relatively complicated.

An object of the invention is to provide a method of establishing ultrawideband communications for transmitting digital information that necessitates only simple circuits that are available off the shelf and dispenses with synchronization between transmission and reception.

SUMMARY OF THE INVENTION

The invention therefore provides a method communicating useful information taking the form of an analog or digital voltage between at least one transmitter and at least one receiver using UWB signals, said at least one transmitter including a subcarrier modulator, a high frequency oscillator and a transmission antenna, and said at least one receiver including a reception antenna and amplification and demodulation means for discriminating said useful information in a signal received at said reception antenna, which method consists in:

on transmission, generating a narrow frequency band high frequency carrier, modulating said high frequency carrier using a subcarrier with a modulation index at least equal to 10, and modulating said subcarrier using said useful information, and

on reception, demodulating said carrier to extract therefrom said subcarrier and demodulating said subcarrier to extract therefrom said useful information.

Thanks to the above features, the received information is extracted from the transmitted signal by double demodulation, and so synchronization between the transmitter and the receiver can be dispensed with. Moreover, the transmitter and the receiver can be constructed from components that are available off the shelf, which minimizes their cost. It will also be noted that there is no need for a local oscillator for the reception.

According to other beneficial features of the invention:

said subcarrier takes a sinusoidal, sawtooth or triangular form;

said subcarrier has a specific frequency for at least one transmitter/receiver pair;

the frequency of said subcarrier is higher than the spectral bandwidth of said useful information;

said useful information is generated from information in analog or digital form and possibly encoded;

said carrier is demodulated on reception using a delay line;

said delay line produces a time-delay τ according to the following equation:

τ=N4⁢fc
in which N=1, 3, 5, etc; and fcis the center frequency of the UWB signal;

said delay line is made in a circuit taking the form of a surface or bulk acoustic wave line;

said delay line is made with the aid of a coaxial cable.

Other features and advantages of the present invention will become apparent in the course of the following description, which is given by way of example only and with reference to the accompanying drawing.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The transmitter1shown inFIG. 1receives a signal Vinwhose content is to be transmitted to a receiver2like that shown inFIG. 2. The signal Vincan be an analog signal or a digital signal. It is fed to an encoding or encryption circuit3which produces from it a digital signal V1.

The transmitter1further includes a subcarrier generator4which generates a subcarrier signal SP whose frequency is higher than the bandwidth of the signal V1.

The signal V1and the subcarrier signal SP are fed to a subcarrier modulator5which can be a frequency modulator or an amplitude modulator. If frequency modulation is chosen, the subcarrier generator4can take the form of an analog voltage-controlled oscillator (VCO) or a numerically controlled oscillator (NCO). In the latter case, a microprocessor associated with appropriate software can be used. It will further be noted that the subcarrier SP can take various forms, the preferred forms being sinusoidal, sawtooth and triangular.

The transmitter1further includes a high frequency oscillator6to which the modulator signal V2from the modulator5is fed. The signal generated by this high frequency oscillator is used as the carrier for communications between the transmitter1and the receiver2. The signal V2frequency modulates this carrier so that the instantaneous output frequency of the transmitter1is proportional to the signal V2that is fed to the oscillator6. Furthermore, the frequency modulation must be carried out with a modulation index at least equal to 10. The oscillator6can equally well be a voltage controlled oscillator (VCO). The output signal V3of the oscillator6includes a UWB signal with a content which reflects that of the signal Vinapplied to the input of the transmitter1. The output signal V3is sent to a transmission antenna7.

The frequency of the subcarrier SP can be chosen specifically for a given transmitter/receiver pair or for a group of such transmitter/receiver pairs so that communication is confidential to the pair or group.

The communication is received by a reception antenna8of the receiver2, which is connected to a preamplifier9to which the received signal V4is fed to increase its level before demodulation. The preamplifier9can include filter means for rejecting any signal component caused for example by interference received at the antenna8outside the concerned frequency band. A wideband FM demodulator10is connected to the output of the preamplifier9, from which it receives the signal V5, from which it extracts the baseband signal or subcarrier V6. The output of the demodulator10is connected to a subcarrier demodulator11which extracts from the demodulated subcarrier the encoded or encrypted signal V7. The content of the latter corresponds to the signal V1processed in the transmitter1. The signal V7is then decoded or decrypted in a decoder12supplying an output signal Voutcorresponding to the original signal Vinapplied to the input of the transmitter1.

The demodulator10preferably takes the form of a delay line demodulator. A limiter amplifier13connected to the output of the preamplifier9is adapted to eliminate any amplitude modulation component in the signal V5. The output of the limiter amplifier13is fed to a multiplier14and to a delay line15for introducing a time-delay τ. The time-delay is preferably chosen so that:

τ=N4⁢fc
in which N=1, 3, 5, etc. and fcis the center frequency of the UWB signal carrier.

BRF=2⁢fcN
is the useful output of the demodulator10. For example, if N=3, the bandwidth is 0.67×fc.

The delay line15can be formed by a surface or bulk acoustic wave line, which can be integrated into the same circuit as the circuitry of the receiver2. A simple coaxial cable or a microstrip line can also provide a delay line.

FIG. 3shows by way of example the frequency spectrum obtained with the method of the invention, using a center frequency of 69 MHz and a high frequency power of 1 mW. The spectrum features a FM spectral band spreading including a multitude of low-energy spectral components. The bandwidth of the UWB signal is equal to 20 MHz in this example. In one example of implementing the method according to the invention, the following components, all of which are available off the shelf, can be used: