WO2008067851A1 - System for wireless communication - Google Patents

Abstract

The invention relates to a system for wireless communication having a transmission unit and at least one reception unit, characterized in that the transmission unit S uses a transmission carrier frequency Flo to transmit a modulated signal which contains not only a modulation spectrum MS but also its mirror band SB, and the reception unit contains means AE in order to take prescribed criteria as a basis for selecting and demodulating either the modulation spectrum MS or its mirror band SB. This makes it possible to attain the advantage that the transmission certainty can be significantly increased in comparison with the situation in which only a modulation spectrum is transmitted, since interfering influences on the transmission path from the transmission unit to a reception unit only rarely affect both the frequency ranges of the modulation spectrum and those of its mirror band.

Description

 description

Wireless communication system.

Technical area

The invention relates to a system for wireless communication with a transmitting unit and at least one receiving unit.

Background Art In wireless communication technology, interference from a variety of effects is very common, therefore, methods have been developed to improve transmission security.

One of these methods, the so-called "frequency diversity method", improves the transmission reliability by transmitting the same information at different frequencies simultaneously, exploiting the effect that different frequency ranges offer different transmission characteristics and interference signals usually do not affect all frequencies used choose the frequency that gives the most favorable reception situation at its location.

However, this "frequency diversity method" is very expensive since the transmitter according to the prior art must contain a plurality of complete transmission devices corresponding to the number of different frequencies used can be used to determine the optimal frequency.

An important term in wireless communication is the so-called modulation. This is understood to mean the imposition of information on a carrier signal, which may for example also be a DC signal with the frequency 0. In this case we are talking about baseband modulation. Frequently, however, the modulation is used to put the modulated signal in a different frequency band, and adapt the transmission characteristics to special requirements. In this case we are talking about a bandpass modulation. The information is transmitted by the carrier properties, such as amplitude and / or phase. Thus, others, especially higher

Frequency ranges for wireless transmission available. A variety of modulation methods are known, for example the frequency modulation, the phase modulation, the amplitude modulation and many, for each own applications advantageous, further method.

Amplitude modulation is one of the simplest and most commonly used modulation techniques. An amplitude-modulated signal is produced by multiplying the useful signal by a, generally substantially higher-frequency, carrier signal. Very often, the final carrier frequency position is achieved by an intermediate step, in which case the modulation is first impressed on an intermediate frequency with fixed frequency and converted in a next step in the final frequency position.

The spectrum of an amplitude-modulated signal consists of the carrier signal and the two so-called sidebands, which both contain identical information content, that of the useful signal. If the modulation is first impressed on an intermediate frequency carrier, two frequency bands are formed around this intermediate frequency carrier, the upper and lower sideband. By further multiplication with a local oscillator signal - a so-called Übertragungstrager - the final transmission signal is obtained. This includes a two-sided modulation spectrum and its mirror band on the other frequency side of the local oscillator. The mirror band is usually suppressed in practical applications because it contains the same information as the modulation spectrum and, moreover, in many applications leaves the frequency range prescribed by regulations. In order to suppress the unwanted mirror band, expensive circuits such as filters or I / Q modulators in the transmitter unit are required.

The application of the method described above is of course not limited to the amplitude modulation.

Presentation of the invention

The invention has for its object to provide a system by which a communication of a

Sending unit can take place with one or more receiving units and the transmission reliability is increased.

The effort on components should be kept low.

The object is solved according to the invention with a system for wireless communication with a transmitting unit and at least one receiving unit, in which the transmitting unit emits a modulated signal at a carrier frequency, which also contains its mirror band in addition to a modulation spectrum, and the receiving unit contains means for selecting or demodulating either the modulation spectrum or its mirror band as a function of predetermined criteria.

With the invention, the characteristics of a 2 frequency diversity transmission can be achieved with very little effort. This low cost of components also leads to a high reliability, lower space requirements and lower power consumption.

Since the signal emitted by the transmitting unit contains the respective image frequencies in addition to the two side bands, it is possible, for example, to omit the filters or I / Q modulators provided in conventional transmitting circuits. In addition to these cost and complexity reduction effects, the information is simultaneously transmitted in two frequency bands and thus an inherent frequency diversity is realized.

A further advantageous feature of the solution is that the carrier signal is suppressed and thus the entire transmitted power is conducted into the side band containing the information and its mirror band.

It is favorable if the reception quality of the demodulated signal is provided as a predetermined criterion for the selection of one of the side bands. This can be the Transmission reliability can be increased to a particular extent.

It is also favorable, if as receipt quality the error rate of a digital transmitted over the system

Signal is used. This error rate can be easily determined and provides a reliable statement about the property of the transmission channel.

It is recommended that a frequency band is provided for the transmission, which is released for "Industrial, Scientific, Medical" applications.These ISM frequency bands are released for use by the public, there are no fees for the use of The advantage of the invention is particularly great in applications in which a larger number of transmitting units is required, this is especially given in the transmission of sensor signals in the 2.4 and 5.6 gigahertz ISM band.

It is also favorable if a M-ary FSK (Multiple Frequency Shift Keying) method is used as the modulation method, since this also reduces the complexity of the receiving unit while maintaining a robust one

Modulation method is kept low. In particular, the application of a binary FSK method with a large stroke leads to realization advantages for receiving units.

A further, particularly advantageous application is given in the context of near-field communication, since in the low-frequency range provided for near-field communication, the filters to be provided according to the state of the art in the Transmitting units are particularly complex, but omitted according to the invention.

Brief description of the drawings

They show by way of example:

Fig. 1 shows the typical spectrum of a signal in

Double sideband modulation.

Fig. 2 is a functional diagram of a transmitting unit according to the invention

Fig. 3 is a block diagram of a system according to the invention

Fig. 4 is a functional diagram of an inventive

Receiving unit.

5 shows a functional diagram of an embodiment of a transmitting unit

Embodiment of the invention

FIG. 1 shows a spectrum of a signal which consists of an intermediate frequency carrier signal Ft and the two associated sidebands USB and OSB. Such a signal is typical for double sideband modulation. The horizontal axis represents the frequency f, the vertical axis the signal level Sig.

In the system according to the invention, such a signal arises as a result of a first modulation of the modulation signal Fmod with the intermediate frequency carrier signal Ft. A suppression of the intermediate frequency carrier signal Ft or of a sideband USB, OSB can take place, but is of no relevance to the invention. FIG. 2 shows a functional block diagram of a transmitting unit S and the respectively generated spectra, wherein according to the invention the modulation spectrum MS and its mirror band SB are transmitted. A modulation frequency Fmod is by means of a first modulation stage Ml to a

Intermediate frequency carrier Ft aufmoduliert. The resulting spectrum Sigl corresponds to the spectrum shown in FIG. By means of a further modulation stage M2 multiplication with a Ubertragungstrager FIo, so that the signal is brought into the desired Ubertragungsfrequenzlage, wherein the modulation spectrum MS and the associated mirror band SB are maintained. The applied multiplication suppresses the transmission carrier FIo. The figure also includes negative spectral components, which merely form a statement that the applied

Modulation method generates a real signal. The signal Sig2 applied to the output of the second modulation stage M2

FIG. 3 shows, by way of example and schematically, a block diagram of a conversion according to the invention. The transmitting unit S transmits a signal Sig2 with the spectrum shown in FIG. 2, which is received by a receiving unit E. This receiving unit E demodulates the received signal Sig2 and makes it available to an evaluation decision unit AE. This evaluation decision unit AE determines the reception quality on the basis of criteria from the received signal Sig2 and switches the reception unit E to the reception of the modulation band MS or its mirror band SB by means of a frequency selection FA. This can be achieved, for example, by selecting the frequency selection FA between two, on the Mirror band frequencies tuned, generated by quartz frequencies, which are provided to the receiver E as an intermediate frequency. Furthermore, the frequency selector FA can drive, for example, a PLL (Phase Locked Loop) in order to generate the two required frequencies.

If the band to which has been switched turns out to be no better than the originally used band, then the evaluation decision unit AE switches back to the originally used band. This ensures that the band offering the most favorable transmission conditions is selected.

As criteria for the change to the modulation spectrum MS or its mirror band SB, various measured variables determined from the received signal can be used. For example, the reception level of the modulation spectrum MS or its mirror band SB can be determined in order to derive therefrom the criterion for switching to the respective other band.

It is particularly beneficial when transmitting a digital signal over the system containing control information which allows signal quality measures such as e.g. To determine and evaluate bit error rate or packet error rate. These signal quality measures are used as the basis for selecting either the modulation spectrum MS or its mirror band SB.

FIG. 4 shows a functional diagram of an exemplary receiving unit E, the receiving signal being alternative demodulated either by means of a first demodulation frequency Flol or a second demodulation frequency Flo2. The selection of the demodulation frequency to be used is made by the evaluation decision unit AE, which makes this selection depending on certain criteria.

5 shows a functional diagram of a favorable embodiment of a transmitting unit S with which a frequency shift keying method is implemented. 2 frequency generators, such as quartz oscillators QOl, QO2 or ceramic oscillators, etc. which each have slightly different, adapted to the desired spectrum of the transmitted signal frequencies are of, in this case digital modulation signal Fmod respectively alternatively, via a signal former SF and a frequency divider FT, on the modulated in this case also digital transmitter signal. When using the system for high-frequency ISM bands as a transmission channel, the divider and / or the signal conditioning stage can be omitted. The XOR gate X can also be replaced by a multiplier.

List of terms

S transmitting unit E receiving unit

USB lower sideband

OSB Upper sideband

AE analysis decision-making unit

FA Frequency Selection Sig Signal strength f Frequency

Fmod modulation signal

FIo transmission bearer

Flol Demodulation Frequency 1 Flo2 Demodulation Frequency 2

Ft intermediate frequency carrier signal

MS modulation spectrum

SB mirror tape

FT frequency divider QOl First quartz oscillator

QO2 second quartz oscillator

SF signal conditioning stage

FT frequency divider

X XOR gates

Claims

claims

1. A system for wireless communication with a transmitting unit and at least one receiving unit, characterized in that the transmitting unit S transmits a modulated signal on a Ubertragungstraagerfrequenz FIo, which also contains its mirror band SB in addition to a modulation spectrum MS, and the receiving unit comprises means AE to in Depending on predetermined criteria, either the modulation spectrum MS or its mirror band SB to select and demodulate.

2. System according to claim 1, characterized in that as a predetermined criterion for the selection of either

Modulation spectrum MS or its mirror bands SB, the reception quality of the demodulated signal is provided.

3. System according to claim 1, characterized in that the error rate of a digital signal transmitted via the system is used as receiving quality.

4. System according to one of claims 1 to 3, characterized in that the frequency band is a frequency band which is used for "Industrial, Scientific, Medical" applications frequency band is used.

5. System according to any one of claims 1 to 4, characterized in that a M-ary FSK (frequency shift keying) method is used as the modulation method.

6. System according to one of claims 1 to 5, characterized in that the transmission takes place by means of the near field communication.