DE102004039674A1 - Arrangement for signal transmission between first base stations, radio communications terminal has duplexer with two transmission-reception filters tunable to two carrier frequency ranges of FDD radio signal transmission - Google Patents

Abstract

The arrangement has a forwarding base station between the first base station and the terminal with an antenna, a duplexer, first and second transmission paths and first and second reception paths. The duplexer (DUP) contains first and second transmission-reception filters (SEF1,SEF2) that can be tuned to first and second carrier frequency ranges of the Frequency Division Duplex radio signal transmission.

Description

The The invention relates to an arrangement for FDD radio signal transmission between a first base station and a radio communication terminal having a forwarding base station between the first base station and the radio communication terminal is arranged.

to Extension of a radio cell or to increase a base station range It is known to use so-called forwarding base stations.

3 shows in a simplified representation of a forwarding base station WBS, which is arranged between a first base station BTS and a radio communication terminal FKE of a subscriber.

One signal Tx1BTS sent from the first base station BTS as the first received signal Rx1 via an antenna A to the forwarding base station WBS. The first Receiving signal Rx1 is assigned to a first carrier frequency range. The forwarding base station WBS forms from the first received signal Rx1 in the same carrier frequency range a corresponding first transmission signal Tx1, which is emitted via the antenna A. is received as a received signal Rx1FKE to the radio communication terminal FKE.

Corresponding becomes a signal Tx2FKE sent from the radio communication terminal FKE with associated second carrier frequency range over the Antenna A as a second received signal Rx2 at the forwarding Base station WBS received. The second received signal Rx2 is in same carrier frequency range converted into a second transmission signal Tx2, which is emitted via the antenna A. and arrives at the first base station BTS as a received signal Rx2BTS.

at an FDD radio transmission method in a downward direction, the so-called "downlink", from a base station to a radio communication terminal, a first carrier frequency range used while in an upward direction, the so-called "uplink", from the radio communication terminal to the base station a second carrier frequency range is used.

A Subscriber discrimination is achieved, for example, by using subscriber-specific spreading codes, subscriber-specific time slots or a combination of spreading codes on the one hand and time slots realized on the other hand.

The forwarding base station is taking into account the selected radio transmission method or the selected one Subscriber discrimination between the base station and the radio communication terminal accordingly arranged.

4 shows based on 3 a frequency assignment in a radio communication system using an FDD radio transmission method for data transmission.

there shows a horizontal axis times or time slots t1 to t4 on while on the vertical axis carrier frequency ranges FRQ1 and FRQ2 are applied.

The first base station BTS transmits the signal at a first time t1 Tx1BTS, which is a first carrier frequency range FRQ1 is assigned. On the part of the forwarding base station WBS this received as a first received signal Rx1 and in the same carrier frequency range FRQ1 converted into the first transmission signal Tx1. The first transmission signal Tx1 is during a second time t2 transmitted to the radio communication onsendgerät FKE and received there as signal Rx1FKE.

Corresponding is sent at the second time t2 from the radio communication terminal FKE Signal Tx2FKE associated with a second carrier frequency range FRQ2 is, at the forwarding base station WBS as a second received signal Rx2 received. After the conversion of the second received signal Rx2 in the second transmission signal Tx2 with associated second carrier frequency range FRQ2 becomes this at a third time t3 to the first base station Transfer BTS and received there as signal Rx2BTS.

At the FDD radio transmission method Sends and receives signals simultaneously. So will while of the first time t1, a third transmission signal Tx3 with associated second carrier frequency range FRQ2 from the forwarding base station WBS to the first base station Transfer BTS and received there as signal Rx3BTS. During the third time t3 becomes a signal Tx3BTS with associated first carrier frequency range FRQ1 from the first base station BTS to the forwarding base station Transfer WBS and received there as the third received signal Rx3.

Show below 5 and 6 regarding 4 a typical RF front-end architecture according to the prior art for a FDD radio transmission method, which uses a TDMA multiple access method for subscriber discrimination.

The forwarding base station WBS in this case has the antenna A, a switch S, a first Duplexer DUP1, a second duplexer DUP2, a first reception branch EZ1, a second reception branch EZ2, a first transmission branch SZ1 and a second transmission branch SZ2.

Of the first duplexer DUP1 includes a first bandpass filter BPF11, the reception side to the first carrier frequency range FRQ1 fixed is matched, and a second bandpass filter BPF12, the transmission side to the second carrier frequency range FRQ2 is firmly tuned. The second duplexer DUP2 includes the receiving side a first bandpass filter BPF21 which is on the second carrier frequency range FRQ2 is fixed, and a second band pass filter on the transmitter side BPF22, which is on the first carrier frequency range FRQ1 is firmly tuned.

5 shows at time t2 the second received signal Rx2, which corresponds to the signal Tx2FKE of the radio communication terminal FKE, and the first transmission signal Tx1.

The second received signal Rx2 passes through the antenna A and via the Switch S to the second duplexer DUP2. The first bandpass filter BPF21 of the second duplexer DUP2 is at the second carrier frequency range FRQ2 tuned so that the second received signal Rx2 over the first Bandpass filter BPF21 to a low-noise amplifier LNA of the first Receive branch EZ1 passes. The amplified second received signal Rx2 is then fed to a signal processing device M which from this forms the second transmission signal Tx2.

The first transmission signal Tx1 passes from the device for signal processing M over a power amplifier PA of the first transmission branch SZ1 to the second Bandpass filter BPF22 of the second duplexer DUP2, the first Carrier frequency range FRQ1 is tuned. about the second bandpass filter BPF22 reaches the first transmission signal Tx1 the switch S and from this to the antenna A to radiate to the radio communication terminal FKE to become.

6 shows at time t3, the third received signal Rx3 corresponding to the signal Tx3BTS the first base station BTS, and the second transmission signal Tx2.

The third received signal Rx3 passes through the antenna A and over the Switch S to the first duplexer DUP1. The first bandpass filter BPF11 of the first duplexer DUP1 is at the first carrier frequency range FRQ1 tuned so that the third received signal Rx3 over the first bandpass filter BPF11 to a low-noise amplifier LNA of second reception branch EZ2 passes. The amplified third received signal Rx3 is then supplied to the signal processing means M, which this transforms it into another transmission signal for the radio communication terminal FKE.

The second transmission signal Tx2 passes from the device for signal processing M over a power amplifier PA of the second transmission branch SZ2 to the second Bandpass filter BPF12 of the first duplexer DUP1, the second Carrier frequency range FRQ2 is tuned. about the second bandpass filter BPF12 passes the second transmission signal Tx2 to the switch S and from this to the antenna A, to the first Base station BTS to be radiated.

ever after the position of the switch S, which is connected via a signal ST is, are thus at the same time each a transmission branch SZn and each a reception branch EZn with n = 1, 2, connected to the antenna A, whereby the simultaneous Transmission and reception of the HF frontend is ensured. For example the first reception branch EZ1 with the first transmission branch SZ1 or second reception branch EZ2 with the second transmission branch SZ2 alternately the antenna A is switched.

It Object of the present invention, an arrangement for FDD radio signal transmission between a first base station and a radio communication terminal under Use a forwarding base station, which with little effort is feasible.

These The object is solved by the features of claim 1. advantageous Further developments are specified in the subclaims.

The inventive arrangement used instead of two duplexers with fixed bandpass filters just a duplexer, the two adjustable transceiver filters having.

By the arrangement according to the invention is thus saving a more expensive duplexer. Because duplexer due to the individual Construction take up a lot of space is due to the inventive arrangement additionally a volume saving on the part of the forwarding base station allows.

tunable Duplexers are currently under development and will be, for example in "Tunable HF filter or duplexer by ferroelectric detuning of acoustic Resonators, "Dr. Gao et al., IPCOM # 000016452D, 23.06.2003, in the electroacoustic Resonators detuned by paraelectric-ferroelectric varactors become.

In "Method for filtering in a frequency tunable RF front-end duplexer ", Carlos Civeira Munos, IP-COM No. 000019474D, 16.09.2003, A center frequency tuning of an RF front-end duplexer is described.

These Due to their tunability, duplexers are particularly suitable for use in an RF front-end of a forwarding base station for an FDD radio transmission method.

following the invention will be explained in more detail with reference to a drawing. Showing:

1 the arrangement according to the invention for transmitting and receiving a first signal pair,

2 the arrangement according to the invention for transmitting and receiving a second signal pair,

3 the simplified representation explained in the introduction to the introduction with a forwarding base station,

4 the frequency assignment explained in the introduction to the description in an FDD radio communication system, and

5 . 6 the explained in the introduction introduction RF front-end architecture of the forwarding base station.

1 shows with reference to 4 the inventive arrangement for transmitting and receiving a first signal pair, consisting of the second received signal Rx2 and the first transmission signal Tx1.

The forwarding base station WBS includes an antenna A, a Duplexer DUP, a first switch S1, a second switch S2, a first reception branch EZ1, a second reception branch EZ2, a first transmission branch SZ1, a second transmission branch SZ2, a Means for signal processing M and a control device CTRL.

Of the Duplexer DUP includes a first transmit-receive filter SEF1 and a second Transceiver filter SEF2, each individually to the first carrier frequency range FRQ1 or the second carrier frequency range FRQ2 are tunable.

The from the radio communication terminal FKE transmitted signal Tx2FKE with assigned second carrier frequency range FRQ2 passes as a second received signal Rx2 via the antenna A to the duplexer DUP. Provided that its first transmit-receive filter SEF1 to the second carrier frequency range FRQ2 is tuned, the second received signal Rx2 arrives at the first switch S1.

Of the first switch S1 is over the control device CTRG is switched such that the second received signal Rx2 to a low-noise amplifier LNA of the first reception branch EZ1 arrives. The reinforced second received signal Rx2 passes to the device for signal processing M, from which the second transmission signal Tx2 with associated second carrier frequency range FRQ2 forms.

The first transmit signal Tx1 with associated first carrier frequency range FRQ1 passes from the device for signal processing M via a power amplifier PA of the second transmission branch SZ2 to the second switch S2, which is controlled is switched by the control device CTRG such that the increased first transmission signal Tx1 to the second transmission-reception filter SEF2 of Fed duplexer DUP becomes.

The second transceiver filter SEF2 is at the first carrier frequency range FRQ1 matched, causing the first transmit signal Tx1 to the antenna A for radiation to the radio communication terminal FKE arrives.

2 shows with reference to 4 and 1 the inventive arrangement for transmitting and receiving a second signal pair, consisting of the third received signal Rx3 and the second transmission signal Tx2.

The from the first base station BTS sent signal Tx3BTS with associated first carrier frequency range FRQ1 arrives as the third received signal Rx3 via the antenna A to the duplexer DUP. Provided that its second transmit-receive filter SEF2 on the first carrier frequency range FRQ1 is tuned, the third received signal Rx3 arrives at the second switch S2.

Of the second switch S2 is over the control device CTRG is switched such that the third received signal Rx3 to a low-noise amplifier LNA of the second reception branch EZ2 arrives. The reinforced third received signal Rx3 reaches the device for signal processing M, which forms a further transmission signal for later emission to the radio communication terminal FKE.

The second transmission signal Tx2 with associated second carrier frequency range FRQ2 passes from the device for signal processing M via a power amplifier PA of the first transmission branch SZ1 to the first switch S1, which is controlled by the control device CTRG is switched such that the amplified second transmission signal Tx2 the first transmission-reception filter SEF1 of the duplexer DUP is supplied.

The first transmit-receive filter SEF1 is at the second carrier frequency range FRQ2 matched, causing the second transmit signal Tx2 to the antenna A for emission to the first base station BTS arrives.

The Tuning of the two transmit-receive filters SEF1, SEF2 is through the control device CTRL controlled. The control of the two switches S1 and S2 and the tuning of the two transmit-receive filters SEF1, SEF2 is dependent from the used FDD radio transmission method.

The Transceiver filters SEF1, SEF2 are in an advantageous development as a tunable ceramic microwave filter with ferroelectric Varactors are realized or so-called MEMS varactors (Micro Electro Mechanical System, MEMS). This is a Comb filter (Notch) using variable transmission poles tune.

is For example, to receive a signal whose carrier frequency range greater than is a center frequency of the comb filter, so is its transmission pole in terms of frequency above of the signal to be received detuned.

In the case, the signal to be received has a carrier frequency range, which is smaller than the center frequency, the transmission pole becomes in frequency below of the signal to be received detuned.

Claims (3)

Arrangement for FDD radio signal transmission between a first Base Station (BTS) and a Radio Communication Terminal (FKE) with a forwarding base station (WBS) between the first Base Station (BTS) and the Radio Communication Terminal (FKE) is arranged - at the forwarding base station (WBS) an antenna (A), a Duplexer (DUP), a first and a second transmission branch (SZ1, SZ2) and a first and a second reception branch (EZ1, EZ2), - in the the duplexer (DUP) has a first and a second transmit-receive filter (SEF1, SEF2), each on a first and on a second Carrier frequency range (FRQ1, FRQ2) of the FDD radio signal transmission are tunable, - at the antenna (A) during a first time (t3) via the first transmit-receive filter (SEF1) with the first transmission branch (SZ1) and while a second time (t2) with the first reception branch (EZ1) connected is, - at the antenna (A) during of the first time (t3) via the second transmit-receive filter (SEF2) with the second receive branch (EZ2) and during of the second time (t2) connected to the second transmission branch (SZ2) is, whereby during the first time (t3) via the antenna (A) received first received signal (Rx3) with associated first carrier frequency range (FRQ1) to the second receiving branch (EZ2) for further signal processing (M) arrives and a second transmission signal (Tx2) of the first to be transmitted Sending branch (SZ1) with assigned second carrier frequency range (FRQ2) the antenna (A) comes to radiation, and thereby during the second time (t2) via the antenna (A) received second received signal (Rx2) with associated second carrier frequency range (FRQ2) to the first receiving branch (EZ1) for further signal processing (M) reaches and a first transmission signal to be transmitted (Tx1) of the second Sending branch (SZ2) with assigned first carrier frequency range (FRQ1) to the Antenna (A) radiates. Arrangement according to claim 1, characterized in that the first and the second transmit-receive filter (SEF1, SEF2) by a respective comb filter detuning during operation respectively to the first and the second carrier frequency range (FRQ1, FRQ2) are tunable. Arrangement according to claim 1 or 2, characterized - that the forwarding base station (WBS) a first and a second Includes switches (S1, S2), - that the first reception branch (EZ1) and the first transmission branch (SZ1) via the first switch (S1) alternately are connected to the first transmit-receive filter (SEF1), and - that the second reception branch (EZ2) and the second transmission branch (SZ2) via the second switch (S2) alternately with the second transmit-receive filter (SEF2) are connected.