DE19536526A1 - Receiver architecture for receiving angle-modulated / keyed carrier signals of different frequencies - Google Patents

Abstract

In order to combine the advantage of high integratability in the case of a homodyne receiver with the advantages of a heterodyne receiver in receiver architecture for receiving angle-modulated/scanned carrier signals of different frequency, the receiver architecture has a two-stage synthesizer (SYN) with a first local oscillator (LO1) of fixed frequency in a first synthesizer stage (SYNS1) and a second local oscillator (LO2) of adjustable frequency in a second synthesizer stage (SYNS2). The mixers in the second synthesizer stage (SYNS2) are designed so as to form a mixer arrangement (MA) for rejecting image frequencies formed in the first synthesizer stage (SYNS1).

Description

The invention relates to a receiver architecture for receiving gene of angle-modulated / keyed carrier signals under different frequency according to the preamble of claim ches 1.

Receiver architectures of the type described above used in communications engineering wherever an as Carrier serving to be transmitted by modulation with one analogue or digital NF-Si containing information Re-gnal connected RF signal by demodulation is riding. Depending on the use of an analog or the digital LF signal, one differentiates between an analogue or digital modulation or demodulation art. To distinguish the two types, digita len modulation or demodulation the term "keying" ver turns.

For each type of modulation or demodulation (analog or di gital) there are different modulation and demodulation modes lation forms. A distinction is made between an ampli tuden, frequency and phase modulation or amplitude, Fre quenz and phase demodulation. There are also especially with the digital modulation or demodulation type numerous derivatives for the above modulation or forms of demodulation (e.g. GFSK, GMSK, etc.). The Fre frequency and phase modulation or frequency and phase demodulation lation is also be used as angle modulation or demodulation draws.

The above statements relate to a single one to be modulated or demodulated RF signal for the Message transmission in a messaging system, e.g. B. one  Mobile radio system or cordless telecommunication system, ei is available to a limited group of participants.

To increase the number of participants, the number of dimensions sions for analog or digital modulation or demodulation lation increased. For this purpose, the time and / or Frequency range exploited. Alternatively, it is also possible Lich, defined by the time and frequency range Transmission channel additionally through different coding to take advantage of. When using the time and / or fre frequency range one speaks of a TDMA and / or FDMA ver drive (Time Division Multiple Access; Frequency Division Multiple access). When using the time and frequency area in connection with the use of different Coding is called a CDMA process (Code Divi sion multiple access).

In mobile radio technology according to the GSM standard (Groupe Sp´cia le Mobile or Global System for Mobile Communication; see. Informatik Spektrum 14 (Jun. 1991), No.3, Berlin; A. man: "The GSM standard - the basis for digital European mobiles funknetze "; pages 137 to 152) including the derivative DCS1800 and the American Version ADC and Japanese version JDC see above as in cordless telecommunications technology according to the DECT Standard (Digital Kuropean Cordless Telecommunication; cf. Telecommunications Electronics 42 (Jan./Feb. 1992), No.1, Berlin; U. Pilger: "Structure of the DECT standard"; Pages 23 to 29) including America Version WCPS, the CT2 and CT3 standard (Cordless Telecoinmunication) are therefore Emp catcher architectures for receiving angularly keyed signals used, their frequencies in the GSM system in a frequency band between 890 MHz and 960 MHz and at the DECT system in a frequency band between 1880 MHz and 1900 MHz.

When building a receiver - e.g. B. for the above ge named systems - one generally distinguishes between one  Homodyne receivers (direct receivers) or heterodyne receivers (Superimposed receiver) with single or double fre quota conversion. The homodyne receiver has opposite the He terodyne receivers the advantage that the homodyne receiver ar architecture can be integrated more easily. The heterodyne receiver has compared to homodyne receivers, the advantages that the Selek tivity by a bandpass filter at the intermediate frequency and the variable oscillator can be easily defined and that demodulation at a relatively low frequency takes place. The homodyne receiver is also not special well suited for TDMA systems because most of the Sy stem amplification is made in the baseband amplifier. However, these amplifiers react to very low-frequency Si gnale and are therefore very sensitive to transient response operations by switching between a transmit mode and a receive mode in the TDMA systems (cf. ntz vol. 46 (1993), volume 10, pages 754 to 757).

Fig. 1 shows a known from GB-2,286,950 A1 homodyne receiver (Direct Conversion Receiver), which is a single-stage synthesizer SYN typical for high receiver, with an upstream low-noise amplifier VS and bandpass filter BPF and with a downstream limiting device LE and decoding device DE. The limiting device LE can be used to add an "in phase" component ( 1 component) and a quadrature component (Q component) of the signal to be demodulated by adding or subtracting the 1 component and Q component (e.g. an A component and B component) are generated. This increases the angular resolution in the complex I / Q level. For the demodulation in the decoder DE, the components (signals) are also hard limited (limited), whereby the states "1" or "-1" arise for the I, Q, A and B components.

The object underlying the invention is to egg ne receiver architecture for receiving angle-modulated / keyed Carrier signals of different frequencies ben, which have the advantage of high integrability with a Ho modyn receiver with the advantages of a heterodyne receiver connects.

This task is based on that in the preamble of Claim 1 defined receiver architecture by the specified in the characterizing part of claim 1 Features resolved.

The idea on which the invention is based is that of Receiver architecture of the type mentioned one two stage synthesizer with a local oscillator fixed fre quenz in a first stage of synthesis and a local oscilla adjustable frequency in a second synthesizer stage to provide, which contain in the second synthesizer stage mixer as a mixer arrangement for suppressing mirror frequencies formed in the first synthesizer stage is trained.

Advantageous further developments and applications of the invention are specified in the subclaims.

An embodiment of the invention is explained with reference to FIG. 2.

Fig. 2 shows, starting from the known homodyne receiver according to FIG. 1, a receiver architecture modified with respect to the synthesizer SYN, which combines the advantages of a homodyne receiver with those of a heterodyne receiver. The receiver shown in FIG. 2 is therefore also referred to as a quasi-homodyne receiver. In order to achieve the high degree of integration characteristic of homodyne catchers with the receiver shown in FIG. 2, the local oscillators typical for a homodyne and heterodyne receiver must be integrated for frequency conversion (complete integration).

The problem arises that the realization of the required phase noise of the oscillator is not sufficient. To avoid this problem, a first local oscillator LO1 of a first synthesizer stage SYNS1 in the synthesizer SYN is therefore operated at a fixed frequency. As a result, the bandwidth of the synthesizer SYN can be chosen to be very large, so that the phase noise in the region of interest is essentially determined by the stability of a reference oscillator used, not shown in FIG. 2.

Since the first local oscillator LO1 does not change in frequency is the direct one typical of the homodyne receiver Conversion architecture due to the lack of channel selection not possible. The one received via the antenna in the band pass filter BPF filtered and in the low noise amplifier VS (Low Noise Amplifier) amplified signal, e.g. B. at a DECT receiver architecture the DECT signal, is therefore in the first synthesizer stage SYNS1 to an intermediate frequency puts. However, in contrast to the well-known He terodyne receivers - no channel selection carried out. To the in the implementation of the received signal on the intermediate fre suppressing the resulting mirror frequencies is described in one following the first synthesizer stage SYNS1 Synthesizer level SYNS2 regarding the use in this level used mixers a mixer assembly MA (configuration) applies the reception converted to the intermediate frequency signal converts into the baseband and at the same time the in the first synthesizer stage SYNS1 Spiegelre suppressed sequences. The configuration for image frequency Suppression is also called an "Image Rejection Mixer" configuration tion. The mixer assembly MA in the second Synthesizer stage SYNS2 is used to suppress the game gel frequencies operated by a second local oscillator LO2 ben which, in contrast to the first local oscillator LO1 in  the frequency is adjustable. This will be the above already mentioned channel selection or channel selection implemented.

At the output of the second synthesizer stage SYNS2, the components formed by the mixer arrangement for image frequency suppression are combined to form an I component and a Q component - analogously to the conditions in the homodyne receiver. The channel selection in the baseband is then realized, as in the known homodyne receiver according to FIG. 1, by low-pass filters in the I branch and Q branch.

With the adjoining limiter LE nen - according to GB-2,286,950 A1 - by weighted addition or subtraction of the I component and Q component additionally che components, an A component and a B component be fathered. By doing so in the complex The Win resolution in the complex level can be increased. With this improved angular resolution can thus also receive signals le with a small modulation index in the decoder tung DE can be decoded.

Claims (4)

1. Receiver architecture for receiving angle-modulated / keyed carrier signals of different frequencies, with

• (a) a two-stage synthesizer (SYN) for the synthetic generation of a base signal to be demodulated / decoded with an I component and a Q component from the carrier signal,
• (b) a low-noise amplifier (VS), which is connected upstream of the synthesizer (SYN),

characterized in that

• (c) a first synthesizer stage (SYNS1) of the synthesizer (SYN) is provided, which has a local oscillator (LO1) operated at a constant frequency,
• (d) one of the first synthesizer stage (SYNS1) downstream second synthesizer stage (SYNS2) of the synthesizer (SYN) is provided, which has a variable local oscillator (LO2) and a mixer arrangement (MA) for suppressing image frequencies in the synthetic Generation of the basic signal to be demodulated / decoded has.

2. Use of the receiver architecture according to claim 1 in egg a DECT-specific cordless telecommunications system. 3. Use of the receiver architecture according to claim 1 in egg a GSM-specific mobile telecommunications system.