JP2002511673A - Mobile communication signal transmission system - Google Patents

Abstract

(57) Abstract: A transmission system includes a first demodulator that receives an RF mobile communication signal at a first position and demodulates the digital signal into a digital signal, and a first modulator that modulates the digital signal into an RF mobile communication signal. A second modem for receiving an RF mobile communication signal at a second location and demodulating the digital signal to a digital signal; and a second modulator for modulating the digital signal to an RF mobile communication signal. A second modem comprising: a first demodulator output connected to the second modulator by a digital signal transmission medium, and an output of the second demodulator being connected to the first modulator by a digital signal transmission medium. Connected to.

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a mobile communication signal transmission system and distribution system, and more particularly, to a radio frequency (RF) modem.

2. Description of the Related Art A base station in a cellular mobile communication system includes a transmitter that provides an air interface for transmitting and receiving RF mobile communication signals. The base station transmitter is intended for communication with a mobile station or handset moving within the cell provided by the base station. As with all RF communication systems, communication with mobile stations is compromised by physical obstructions, such as buildings and terrain features, that affect the transmission of RF signals. With improved or expanded coverage, RF signals are captured by the antenna and distributed by coaxial cable or other linear analog transmission medium to sites where many mobile stations are located. The RF repeater receives the RF signal and uses analog filtering and amplification techniques to filter the signal and amplify it for retransmission at a higher signal level. These transmission and relay techniques can propagate mobile signals beyond the cell range of the base station to other locations directly distributed to the mobile station, or to provide other coverage of the base station. Retransmitted.

However, the transmission and RF relay techniques described above all operate on modulated RF signals generated by the base station air interface, and thus require a linear analog transmission medium and are simpler. Thus, a more effective and economical medium, or an effective alternative thereof, is desired. [Means for Solving the Problems] According to the present invention, a system for transmitting a mobile communication signal includes a first system at a first position.
A demodulator for receiving the RF mobile communication signal and demodulating the digital signal into a digital signal at a second location, and transmitting the second RF mobile communication signal by modulating the digital signal into a second RF mobile communication signal at a second location A modulator.

Preferably, the transmission system includes a digital signal transmission medium for transmitting the digital signal. The digital signal transmission medium includes a microwave link, an optical fiber link, or a communication line for transmitting digital data. The transmission system of the present invention further comprises, at a first location, a first demodulator for receiving the RF mobile communication signal and demodulating it to a digital signal, and a first demodulator for modulating the digital signal to the RF mobile communication signal. A first modem that includes a modulator; a second demodulator that receives the RF mobile communication signal at a second location and demodulates the digital signal into a digital signal; and a second demodulator that modulates the digital signal into an RF mobile communication signal. And a second modem including a second modulator, wherein the output of the first demodulator is connected to the second modulator by a digital signal transmission medium, and the output of the second demodulator is Connected to the first modulator.

[0005] Preferably, an interface is connected to each of the RF antennas, or one of the interfaces is connected to a base station transmitter. A mobile communication signal modem of the present invention comprises a demodulator for receiving an RF mobile communication signal and demodulating it to a serial digital data signal for transmission over a digital communication link; and a serial digital data signal received over the digital communication link. And a modulator for modulating the RF mobile communication signal into a communication signal.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The transmission or relay system shown in FIG. 1 includes GSM RF modems 4 and 6 connected by a serial 270 kbits / s full-duplex data link 8. Modems 4 and 6 transmit and receive GSM 90 transmitted and received by antennas 10 and 12 respectively connected thereto.
It can modulate and demodulate 0/1800 MHz RF mobile communication signals.

The first modem 4 includes a first RF receiver / demodulator / regenerator 14 connected to the antenna 10 and demodulating a downlink RF signal transmitted by the GSM base station. The downlink signal is an RF signal modulated with GMSK (Gaussian minimum shift keying) of 935-960 / 1805-1880 MHz. The receiver 14 has a communication speed of 2
Demodulates to 70.833 kbits / s standard R5-422 data signal or other data line protocol signal. No equalization or error correction is performed on the communication signal by the receiver 14, and incoherent FM demodulation is employed for simplification and cost reduction. The data stream created by the receiver is sent by link 8 to a second RF transmit modulator of second modem 6. Link 8 is provided by a type of digital transmission medium, as described below. The second transmitter / modulator 18 receives the data stream from the link 8 and conditions the data stream,
Data is modulated to generate a GMSK modulated signal in the 60 / 1805-1880 MHz band. The RF signal is amplified, filtered, and provided to antenna 12 for retransmission.

As a return path for uplink communication to the base station, the second modem 6
The first modem 4 comprises a first RF transmitter / modulator 16, which comprises a first receiver 14 and a second modulator 18 respectively. But the former is 890-915 / 1710-17 for the uplink band
Operates at 85 MHz RF frequency. Modulators 16 and 18 generate an RF GSM signal that is essentially equivalent to that received by receiver 14 or 20 of the other modem. However, the signal is delayed by the propagation delay of the system 2 and the second modulator 1
8 have different amplitudes for the retransmitted signal and typically have different amplitudes for the first modulator 16 on the uplink path. The amplitude of the retransmission signal on the uplink path depends on the power of the mobile handset or station, and the handset and the second receiver 20
Independent of the path loss between The first modem 4 is connected directly to the transmitter of the base station. Each of the modems 4 and 6 provides a GSM air interface and a serial data interface.

The receivers 14 and 20 of the modems 4 and 6 are substantially superheterodyne receivers 22 including a data slicer for generating a serial data signal, as shown in FIG. Receiver 22 filters and amplifies the incoming RF signal and mixes this signal with a local oscillator signal generated by frequency synthesizer 24. The frequency is selected depending on whether it operates in the downlink mode or the uplink mode. This results in an intermediate frequency (IF) signal, which is filtered by a surface acoustic wave (SAW) filter and sent to a second mixer where the crystal oscillation of the receiver 22 is generated to generate a second IF signal. Are mixed by the local oscillation signal. Second IF
The signal is filtered, amplified, limited and sent to a quadrature demodulator. The output signal of the quadrature demodulator is an analog baseband signal representing the original Gaussian filtering data contained in the RF signal. The voltage levels of the analog signals are compared by a data slicer to generate high and low signals that provide a 270.833 kbits / s digital data stream in NRZ TTL format.
To increase the transmission distance of the NRZ TTL data, a driver / converter 26 is used to convert the data to a balanced transmission format conforming to the Electronic Industries Association (EIA) standard EIA-422-A. Drivers 26 can be set in a power down mode, allowing multiple drivers to be connected on the same line 28 of data link 8 and operated at different times without affecting each other.

The modulators 16 and 18 of the modems 4 and 6 include a converter 30, a baseband logic circuit 32, a Gaussian filter 34, a quadrature modulator 36, and a clock recovery circuit 38. Converter 30 receives the RS422 data signals on data link 8 and sends them to baseband logic circuit 32 in NRZ TTL format. The clock recovery circuit 38 includes a phase locked loop (PLL) circuit that compares the phase of the data in the NRZ format with the phase of the local oscillator. If the two signals have a phase error between them, that error is used to cause a small shift in the frequency of the crystal oscillator until the phases match. The oscillator is used to provide a continuous clock signal that is in phase with the incoming data and is used to clock the data at the correct transmission rate so that the baseband logic circuit 32 separates the two serial data streams. can do.

The baseband logic circuit 32 provides a recovered clock signal from a clock recovery circuit 38 to generate 135 kbits / s serial in-phase (I) and quadrature (Q) data streams for the quadrature modulator 36. And the incoming data from converter 30. Logic circuit 32 conditions the two output streams, and a correction rotation of the phase vector from quadrature modulator 36 occurs at the appropriate baseband input. For an incoming high signal, logic circuit 32 produces data on the I and Q lines to produce a positive 90 ° phase shift on the output of quadrature modulator 36, while for a low signal , Logic circuit 32 produces data on the I and Q lines to produce a negative 90 ° phase shift.

The I and Q data streams output from the logic circuit 32 are filtered by a Gaussian filter 34 before being supplied to a modulator 36. This requires limiting the bandwidth of the RF spectrum after modulation. The filtering requirement for GSM is specified as a Gaussian filter with a bandwidth of 0.3 bit ratio, resulting in 0.3 Gaussian minimum shift keying (GMSK). The bandwidth of the filter 34 is set to 81.25 kHz. The filter 34 is the fourth
Use a switch-capacitive filter to generate a second-order Gaussian low-pass filter response.

The frequency synthesizer 24 generates an RF signal for converting the modulated signal returning to the channel of the GSM downlink or uplink band in the up direction, and as described above,
Generate an RF signal to the first mixer of the FM receiver 22 for channel selection. For each frequency required for the RF signal, synthesizer 24 has low phase noise.
Includes PLL, high stability reference oscillator, and low noise voltage oscillator (VCO). Based on the channel frequency data loaded into the PLL, the PLL generates V
Drive CO. PLLs use a reference oscillator to provide a reference frequency. The generated channel frequency is loaded into each PLL via a serial data interface.

The quadrature modulator 36 includes a phase shifter connected to two mixers and a combiner. The mixer mixes the I and Q streams with the carrier signal from the frequency synthesizer 24, respectively. The phase shifter is based on the data on the I and Q data streams,
Performing a phase shift on the carrier signal mixed with the Q stream, a combiner combines the two signals to generate a GMSK modulated RF signal, typically generated by a GSM base station transmitter. The output of quadrature modulator 36 is sent to power amplifier 40 for the downlink path to increase the power of the signal to retransmit antenna 12.
Depending on the required coverage, the output power varies between 10 milliwatts and 10 watts. RF duplexer 42 is used to enable both receive and transmit streams for modems 4 and 6 to use one antenna 12 for the air interface.

The transmission system 2 is particularly useful if used in repeater applications at the physical locations required to receive, regenerate and retransmit GSM RF signals. The modems 4 and 6 are effectively located at locations opposite the physical obstacle, with the data links used to effectively send communication signals over the obstacle.
Obstacles are topographical features such as buildings, for example mountains.

As shown in FIG. 3, modems 4 and 6 are used for digital transmission of mobile communication signals from base station 50 to a remote location. Various digital transmission media are used to provide a data link for transmitting a 270 kbits / s data signal to a retransmittable remote location, using a second model 6 if necessary. The digital link is provided by a microwave link, a fiber optic link, or a link typically provided by a standard twisted pair of copper wires for transmitting POTS signals. Microwave links are used to send communication signals to various buildings in an urban business district.

The first modem 4 is used to send communication signals to one of the second modems 6 located at various locations. The downlink signal on the data link 8 is simply replicated to different locations by broadcast or multi-casting using multi-drop transmission. The uplink signals share a common data path to the first modem 4, so gating is needed to allow multiple access to the received GSM TDMA data. Gating is performed based on a received signal strength indicator (RSSI) determined by each receiver 22 of the second modem 6. The receiver 22 uses the RSSI and, according to other available information, drives the receiver to determine that a valid transmission has been received from the handset, and thus switches the RS422 driver 26 connected to the receiver. On and off.

Many modifications will be apparent to those skilled in the art without departing from the scope of the invention described herein. For example, the present invention relates to a digital modulation technique such as GSM (Group
Special Mobile), DECT (Digital European Cordless Telephone), IS54 NADC (
North American Digital Cellular), (or DAMPS (Digital Advanced Mobile Pho
ne System), JDC (Japanese Digital Cellular), CT2 (Cordless Telephone 2) a
nd digital paging systems such as that established by POCSAG (Post Offic
e Standard Advisory Group).

[Brief description of the drawings]

FIG. 1 is a block diagram as a preferred embodiment of a transmission system.

FIG. 2 is a block diagram of an air interface modem of the transmission system.

FIG. 3 is a block diagram of a remote retransmission system using a modem.

Fig. 4 Multi-drop / simulcast using a modem
It is a block diagram of a system.

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Claims (23)

[Claims] 1. A demodulator that receives a first RF mobile communication signal at a first location and demodulates the digital signal into a digital signal; and modulates the digital signal into a second RF mobile communication signal at a second location. A modulator for transmitting the second RF mobile communication signal; and a modulator for transmitting the second RF mobile communication signal. 2. The transmission system according to claim 1, further comprising a digital signal transmission medium for transmitting the digital signal. 3. The transmission system according to claim 2, wherein said digital signal transmission medium is a microwave link. 4. The transmission system according to claim 2, wherein said digital signal transmission medium is an optical fiber link. 5. The transmission system according to claim 2, wherein the digital signal transmission medium includes a communication line for transmitting digital data. 6. A first demodulator that receives an RF mobile communication signal and demodulates the digital signal into a digital signal at a first position, and a first demodulator that modulates the digital signal into an RF mobile communication signal.
A second modem for receiving an RF mobile communication signal and demodulating it into a digital signal at a second location.
And a second modem including a second modulator for modulating a digital signal into an RF mobile communication signal, wherein the output of the first demodulator is output by the digital signal transmission medium. A second modulator, wherein the output of the second demodulator is connected to the first modulator. 7. The transmission system according to claim 6, wherein the first modem and the second modem are connected to a first RF antenna and a second RF antenna, respectively. 8. The transmission system according to claim 6, wherein said first modem is connected to a transmitter of a base station, and said second modem is connected to an RF antenna. 9. The transmission system according to claim 6, including a plurality of said second modems respectively connected to a plurality of RF antennas, said first modem being connected to a base station transmitter. 10. The output of the first demodulator is connected to the second modem of the second modem.
10. The transmission system according to claim 9, wherein the output of the second demodulator of the second modem is selectively connected to the first modulator. 11. The output of the second demodulator is connected to the first modulator based on a received signal enhancement of an RF signal received by the second demodulator.
2. The transmission system according to 1. 12. The first demodulator and the second modulator handle uplink communication signals on a first carrier frequency, and the second demodulator and the first modulator operate on a second carrier. 9. The transmission system according to claim 8, which handles downlink communication signals of a frequency. 13. The transmission system according to claim 6, wherein said first and second modems have an RF mobile communication interface and a serial data interface. 14. The transmission system according to claim 6, wherein said digital signal transmission medium is a microwave link. 15. The transmission system according to claim 6, wherein the digital signal transmission medium is an optical fiber link. 16. The transmission system according to claim 6, wherein the digital signal transmission medium includes a communication line for transmitting digital data. 17. A demodulator for receiving an RF mobile communication signal and demodulating it into a serial digital signal for transmission on a digital communication link, and a modulation for modulating a serial digital data signal received on the digital communication link. And a mobile communication signal modem. 18. The apparatus according to claim 17, further comprising a superheterodyne receiver for mixing a received RF signal with a local oscillation signal generated by a frequency synthesizer, wherein the frequency of the local oscillation signal depends on an operation mode of the demodulator. Modem. 19. The modem of claim 18, wherein the output of the receiver is connected to a digital communication line driver that enables a plurality of the modems to be connected to the link. 20. The modem according to claim 18, wherein the operation mode is an uplink or a downlink. 21. The modulator includes a baseband logic circuit and a quadrature modulator, wherein the baseband logic circuit generates serial in-phase and quadrature data streams to the quadrature modulator based on data received from a digital link. 18. The modem of claim 17, wherein said modem occurs. 22. The quadrature modulator generates the RF communication signal having a carrier frequency determined by a local oscillation signal generated by a frequency synthesizer, wherein a frequency of the local oscillator depends on an operation mode of the modulator. 22. The modem according to claim 21. 23. The modem according to claim 22, wherein the operation mode is uplink or downlink.