DE10307427A1 - Full duplex communication circuit has direct conversion transceivers with synchronisation units to link transmission and reception of FSK digital data - Google Patents

Abstract

A full duplex communication circuit has transmitters with synchronisation units (5) to link the transmission and reception of digital data in duplex connected transceivers connected to the receive path by a detector (7) after the frequency converter (3) or demodulator (4a) so that the start of transmitted and received signals will overlap. Includes Independent claims for the procedures used by the equipment.

Description

The invention relates to a circuit arrangement and a method for direct demodulation.

In modern transceiver circuits, which is also a full duplex operation support -also allowing simultaneous sending and receiving will be in the recipient path mostly IQ demodulators used to process the received signal.

Such a transceiver is for example in 5 shown. The transceiver shown is used to transmit and receive ASK (Amplitude Shift Keying) and FSK (Frequency Shift Keying) modulated data. A signal consisting of symbols received at the upper antenna ANT is passed on to a mixer MIXER after amplification LNA, which mixes the signal down to an intermediate frequency f _IF . The signal mixed to the intermediate frequency is demodulated by an IQ demodulator. The demodulator consists of two paths I and Q, which are fed by signals and are mutually phase-shifted by 90 °. The frequency of the respective paths corresponds to the intermediate frequency F _IF . The signal received and converted to an intermediate frequency is split up and transferred to a mixer, which is located in the I or Q path of the IQ demodulator. The mixer converts the respective share to a final frequency of 0 Hz. This process is also referred to as "direct conversion" and is in 4A can be seen in which a modulated signal located on a frequency RF is converted to 0 Hz by a mixed signal also located on the frequency RF.

In the case of a received signal with FSK-modulated symbols, the width of the spectrum depends on the frequency deviation with which the symbols were modulated. In the example, these are +12 and -12 kHz. After demodulation with the IQ demodulator, the IQ diagram shows the 4B a pointer, the length of which is proportional to the amplitude of the received signal and which rotates with the frequency deviation. The axes I and Q correspond to a projection of the temporal course of the amplitude of the respective path on the amplitude axis. The direction of rotation clockwise or counterclockwise corresponds to the frequency deviation of -12 or +12 kHz and thus represents a symbol of the FSK-modulated signal originally received.

Such an arrangement with a direct IQ frequency conversion due to an IQ demodulator requires a lot of space and power.

The aim of the invention is therefore an arrangement and a method for synchronizing two transmission and receiving arrangements for Demodulation of FSK-modulated signals with reduced space and to provide power requirements.

This task comes with the characteristics according to the sibling claims 1 and 6 solved, which makes it possible to dispense with complete IQ demodulation. Further advantageous refinements are specified in the subclaims.

The invention is based on the idea in a transceiver an arrangement for synchronization between to provide the reception path and the transmission path, so that each Sending a symbol at a fixed time when receiving a symbol in the Reception path linked is. The synchronized transmission symbols are from the first transceiver sent and received by a second who demodulates and in turn synchronized its transmission path.

Is such a time synchronization given, an IQ demodulator can be dispensed with. Demodulation of the received symbols takes place in that a demodulator by the known temporal relationship of an amplitude and phase change at the time of a change of a symbol is detected on a subsequent symbol and from it reconstructed the sent symbols.

Such a demodulator can be advantageous be designed as a phase shift detector.

Advantageously, a vanishing amplitude of the receiver signal synchronized become.

In an overall system consisting of several circuit arrangements can so advantageous except for one all demodulators simple and not be designed as IQ demodulators. Through the continuous Synchronization can be a change in Frequency deviation or an offset of a transmitter frequency between compensate for two different transceivers.

In the following, the invention is made more concrete embodiments explained in more detail with the aid of the drawings.

Show it:

1 an embodiment of the object according to the invention,

2 a further embodiment of the invention,

3 Measurements on the in 4 shown configuration,

4 the frequency-converted spectrum of an FSK-modulated signal with IQ diagram,

5 a known embodiment of a transceiver with "direct conversion".

1 shows a block diagram, consisting from two transceivers 1 and 2 , Both transceivers each have a receive path, designated RX, and a transmit path TX. The reception path contains a device for frequency conversion 3 for mixing or converting the received signal to an intermediate frequency f _IF and a demodulation device 4 in the transceiver 1 and one, unlike the facility 4 differently designed demodulation device 4A of the transceiver 2 , The demodulated symbols are processed further at the output of the reception path RX. The transmission path TX of both transceivers contains a modulator 6 which modulates the symbols to be transmitted on a carrier frequency. The transmission path TX also contains an arrangement 5 , which as a synchronizer establishes a fixed temporal relationship between symbols from the send and receive path. In transceiver 2 is the synchronizer 5 directly connected to the receive path after demodulation of the received signal and synchronized to the received symbols. In transceiver 1 the synchronizer with the converted but not yet demodulated received signal via a further arrangement 7 connected. The order 7 is designed in the execution case as a detector which detects a vanishing amplitude of the converted signal.

After moving one on the transceiver 1 received signal by the mixing device 3 the detector registers 7 a disappearance of the amplitude of the signal received and converted to the intermediate frequency f _IF (zero crossing detection) and gives this to the synchronizer 5 further. The synchronizer thus links the symbol to be sent with a zero crossing of the received signal.

The symbols sent in this way are determined by the reception path of the transceiver 2 received by the mixing device 3 converted to an intermediate frequency and from the arrangement 4A demodulated. The demodulator 4A is designed as an IQ demodulator. At the exit of the arrangement 4A there is a full description of the demodulated symbol by the synchronizer 5 of the transceiver 2 used by the transceiver 2 to synchronize the symbols to be sent with the received symbols. Operation of the transceiver 1 and 2 runs in sync when so from the transceiver 2 sent data from the transceiver 1 received and in turn used for synchronization.

It is possible for the synchronization process the order of transmission and reception of the two transceivers to swap.

A demodulation device 4 of the transceiver 1 is now significantly simpler than the IQ demodulation device of the transceiver 2 ,

In 1 dispenses with the demodulation device 4 on the Q component that is phase-shifted by 90 °, but only evaluates the I-channel. Since a change of a symbol to the next symbol due to the synchronization always takes place at the zero crossing of the received signal, it is sufficient to detect the phase position of the received signal during the zero crossing. A change of the phase by 180 ° corresponds to a change of the data bit from 0 to 1 or vice versa for FSK-modulated symbols.

Another possible embodiment is with the detector 7 not to use the zero crossing, but a maximum or minimum of the received amplitude as a criterion for the synchronization of the symbols to be transmitted.

It is advantageous if both transceivers have the same fixed temporal relationship for the synchronization between received and transmitted data. The demodulation device 4 of the transceiver 2 However, the fixed temporal relationship between the transmission and reception path of the transceiver 1 be known.

In a system with multiple transceivers of the type 1 and a transceiver of the type 2 the arrangement described has an advantageous effect on the overall system costs. It is particularly advantageous, in a network with several transceivers, all transceivers as transceivers of the type 1 train.

With the configuration according to the invention Sending and sending both simultaneously and at different times Receive.

A specific embodiment of a reception path of the transceiver 1 with connected detector 7 shows 2 , One of transceivers 2 The FSK-modulated signal sent is converted directly to 0 Hz by a MIXER frequency conversion device. For this purpose, the mixer uses an oscillator LO, which has the same carrier frequency as the transmitted signal. A low-pass filter LP and a capacitor C are provided for filtering undesired mixed products and the direct current. The signal arrives at an operational amplifier OP, which operates as a limiter and, because of its asymmetrical supply, requires voltage division with the 100 kOhm resistors shown. The rectangular signal is processed for further steepening by two inverted Schmitt triggers ST and then reaches the clock input of a flip-flop circuit FS consisting of two parts. This circuit works as a divider and divides the square wave signal by a factor of 4.

The output of the flip-flop circuit FS corresponds to the output of the detector 7 the 1 which from the synchronizer 5 is used to synchronize the symbols to be sent. In the present exemplary embodiment, this signal SDL is not only used as a synchronization signal for the transceiver 2 used, but also as a data signal. The synchronization and data signal coming from the flip-flop circuit is at an input of the transceiver 2 placed to simplify chung is designed as a universal RF signal generator RF-SIGGEN. The signal generator interprets the square-wave signal as digital states and sends them out as FSK-modulated symbols on a carrier frequency. The transceiver is transmitting at the same time 2 a new symbol on each edge of the square-wave signal.

A two-channel oscilloscope OSZ, which is connected to the first channel on the reception path after the low-pass filter LP and to the second channel on the synchronization and data line SDL, shows in 3A shown measurement. That from the transceiver 2 transmitted FSK signal has a frequency deviation of 12 kHz. By dividing the signal by a factor of 4 in the flip-flop circuit FS, only every fourth zero crossing is used for synchronization.

That from the transceiver 2 The rectangular synchronization signal used as the data signal brings about a switchover from +12 kHz to -12 kHz representing the digital states in the transmission frequency of the transceiver 2 , which causes a phase jump of 180 ° in the received signal converted to 0 Hz, which in 5a in the channel 1 you can see. This phase jump takes place at the time of the transmission of a synchronization signal. A detector circuit determines the two digital states by evaluating an existing phase jump at the time of the synchronization signal.

A change in the frequency deviation in FSK-modulated signals is expressed in the IQ diagram by a changed rotation of the pointer and thus by a changed period of the curve in the channel 1 in 3A , This automatically leads to a changed synchronization period, so that the transmission data rate dependent on the synchronization period is automatically adapted to the respective received data rate in the embodiment according to the invention.

The same applies to an offset between the carrier frequency of the transmitter and the frequency of the LO during the mixing process. Such an example shows 3B , at which the frequency of the local oscillator LO of the transceiver 1 by 6 kHz compared to the carrier frequency of the transceiver 2 is changed. This results in an offset frequency of 6 kHz, and the frequency deviations are no longer ± 12 kHz for the two digital states, but +18 for one and -6 kHz for the other state. Nevertheless, as in 3B to see, only every fourth zero crossing is used for synchronization. Demodulation by an evaluation unit, which reacts to the change of the phase during the synchronization time, is therefore possible without any problems.

Claims (8)

Circuit arrangement consisting of a reception path (Rx) which contains a device for frequency conversion ( 3 ) and a demodulation device ( 4 ) and a transmission path (Tx), which has a modulation device ( 6 ) for the modulation of digital data on a carrier frequency, characterized in that the transmission path has a device ( 5 ) connected to the reception path and the device ( 5 ) is designed as a synchronization device which links the transmission of symbols consisting of digital data with the reception of a signal consisting of symbols by means of a fixed temporal relationship. Circuit arrangement according to claim 1, characterized in that the synchronization device ( 5 ) with a detector arrangement ( 7 ) connected after the frequency conversion facility ( 3 ) is connected to the reception path and if the amplitude of the reception signal of the synchronization device disappears ( 5 ) provides the synchronization signal. Circuit arrangement according to one of the preceding claims, characterized characterized in that the circuit arrangement for sending and receiving digital signals at different times modulated signals is formed. Circuit arrangement according to one of the preceding claims, characterized in that a second arrangement exists, consisting of a transmit (Tx) and a receive path (Rx) which in the receive path have a device for frequency conversion ( 3 ) and a demodulation device ( 4a ) and a synchronization device ( 5 ), the synchronization device ( 5 ) with the receiver path (Rx) after the demodulation device ( 4a ) is connected and the synchronization device ( 5 ) the transmission of symbols consisting of digital data is linked to the reception of symbols by a fixed temporal relationship. Method for synchronizing two transmitting and receiving arrangements, in which one sent by the first transmitting and receiving arrangement Signal is received in the second transmitting and receiving arrangement and a signal associated with a temporal relationship to the received signal the first transmission and reception arrangement is sent back and in the first transmission and reception arrangement the transmission of a signal in a fixed temporal relationship with the received signal is set. A method according to claim 5, characterized in that in both transmit and receive arrangements have the same fixed time Relationship between sending and receiving signals used becomes. A method according to claim 5, characterized in that the start of a symbol to be sent with the start of time of a received symbol. A method according to claim 5 to 7, characterized in that the Transmitting and receiving arrangements as circuit arrangements of claim 1 or 4 are formed.