KR100653515B1 - Mobile station for mobile communication system - Google Patents

Abstract

The present invention provides a method for improving a transmission spurious characteristic without using a SAW filter, which is essentially used in a terminal of a mobile communication system (PCS, DCS, W-CDMA WLL). BACKGROUND OF THE INVENTION The present invention relates to a terminal, which includes a low pass filter (LPF) for low-pass filtering a transmission signal (I, Q) in front of a QPSK modulator and removing baseband 8.192 MHz multiplied clock noise. Can be improved. In addition, the Lumped LC BPF is used instead of the traditional transmit mid-frequency saw filter to reduce the loss of the transmit signal, thereby reducing the amplifier's current consumption. In addition, in order to remove the transmission spurious, a plurality of band filters are conventionally used in the RF stage, and a SAW filter is used in the IF stage. However, the present invention uses only one RF band filter and an LC filter. As a result, the circuit size can be reduced by reducing the circuit components.

Mobile terminal, SAW filter, LC band filter, low pass filter, transmission spurious

Description

Mobile terminal for mobile communication system

1 is a block diagram showing the configuration of a transmitting end of a terminal in a conventional mobile communication system,

2 is a block diagram showing the configuration of a transmitting end of a terminal in a mobile communication system according to the present invention;

3 is a circuit diagram illustrating an example of the low pass filter of FIG. 2;

4 is a circuit diagram showing an embodiment of the LC filter of FIG.

FIG. 5 is a characteristic curve diagram of the LC filter shown in FIG. 4;

FIG. 6 is an RF output spectrum for explaining the characteristics of the low pass filter applied in the present invention. FIG. 6A is an RF output spectrum when a low pass filter is not used at a transmission signal input. FIG. 6B is a low pass filter at a transmission signal input. RF output spectrum when used.

<Explanation of symbols for main parts of the drawings>

101: low pass filter

101a, 101b: low pass filter

102: QPSK Modulator

103: LC low pass filter

106: high frequency band filter

The present invention relates to a terminal in a mobile communication system (PCS, DCS, W-CDMA WLL) to which the CDMA method is applied. In particular, the present invention relates to a transmission spurious without using a SAW filter. It relates to a terminal of a mobile communication system to improve the characteristics.

More specifically, a low pass filter (LPF) is added to the input signal (I, Q) input stages to remove baseband 8.192 MHz multiplied clock noise to improve the transmission spurious characteristics, and to improve the transmission transmission frequency. By using Lumped LC BPF instead of filter, it is related to the terminal of mobile communication system to reduce the loss of transmit signal and reduce the current consumption of amplifier.

In general, a terminal used in a mobile communication system inputs an I, Q waveform, which is a transmission baseband signal, to an intermediate frequency QPSK modulator without further processing, and modulates it into a QPSK signal. This is because it is assumed that the transmission signal input to the baseband has good characteristics. However, in fact, the multiplication frequency of 8.192MHz used to generate the CDMA signal in the baseband is input to the IF stage together with the signal, resulting in 8.192MHz multiplication frequency spurious on the waveform at the RF antenna output stage. Therefore, in order to eliminate such transmission spurious, an expensive and bulky RF dielectric resonator filter and an IF SAW filter have been conventionally used.

1 is a diagram illustrating a configuration of a transmitting terminal of a terminal in a conventional mobile communication system using the RF dielectric resonant filter and the IF SAW filter.

As shown, a QPSK modulator 1 for QPSK-modulating IF baseband signals I and Q and outputting a modulated intermediate frequency and an intermediate frequency IF output from the QPSK modulator 1 are required to be filtered. An intermediate frequency SAW filter 2 for passing only a frequency band, an automatic gain control unit 3 for controlling a gain of a transmission signal through the intermediate frequency SAW filter 2, and a transmission output from the automatic gain control unit 3; A frequency upconverter 4 for up-converting the signal to a high frequency, a first band filter 5 for filtering a high frequency output from the frequency upconverter 4 into a set band, and the first band filter 5 A pre-amplifier 6 for preamplifying the output signal, a second band filter 7 for band filtering the output signal of the preamplifier 6, and an output signal of the second band filter 7 at a predetermined level. A drive amplifier 8 for amplifying with It consists of a final amplifier (9) for finally amplifying and outputting the output signal of the drive amplifier (8).

The transmitting end device of the terminal used in the conventional mobile communication system configured as described above QPSK modulates the IF baseband signals (I, Q) of quadrature components transmitted from the baseband signal processing unit by the QPSK modulator (1). That is, the baseband signal processor receives 140 MHz from an IF PLL synthesizer to generate a local signal having a phase of 0 ° and a local signal having a phase of 90 ° using a phase shifter. Each local signal thus produced is input to the QPSK modulator 1, and the QPSK modulator 1 performs QPSK modulation with an internal In-Phase modulator and a quadrature phase modulator, respectively. Passed to frequency SAW filter (2).

The intermediate frequency SAW filter 2 passes the transmission IF signal at the intermediate frequency IF output from the QPSK modulator 1 and blocks the unnecessary band signal. That is, only the required frequency band (for example, 140MHz) passes through the filtering.

The automatic gain control unit 3 transmits through the intermediate frequency SAW filter 2 using the result of adding the variation of the RSSI value according to the reception level and the power control information transmitted from the base station to perform power control on the reverse link. Control the gain of the signal.

The frequency up-converter 4 up-converts the transmission signal output from the automatic gain control unit 3 to a high frequency RF. Here, the frequency upconverter 4 is supplied with a local frequency of 2455 MHz from the PLL synthesizer.

In addition, the first band filter 5 filters the high frequency output from the frequency up-converter 4 to a set band (2315 MHz).

In addition, the preamplifier 6 pre-amplifies the signal output from the first band filter 5 to compensate for the path loss, and the second band filter 7 bands the output signal of the preamplifier 6. To filter. Here, the second band filter 7 uses an expensive and bulky RF dielectric resonator filter.

The drive amplifier 8 amplifies the output signal of the second band filter 7 to a predetermined level, and the final amplifier 9 finally amplifies the output signal of the drive amplifier 8 to output at a transmission frequency. do.

However, in such a conventional mobile communication terminal, a multiplication frequency of 8.192 MHz used for generating a CDMA signal by the baseband processor is input to the transmitter together with a signal to generate a transmission spurious, which is expensive and bulky to eliminate this. The use of an RF dielectric resonator filter and an intermediate frequency SAW filter has led to the disadvantage of larger device size and higher production cost.

In addition, the power consumption is increased by increasing the amplification degree in the amplifier to compensate for the path loss.

Accordingly, the present invention has been proposed to solve various problems occurring in the conventional mobile communication terminal as described above.

SUMMARY OF THE INVENTION An object of the present invention is to provide a terminal of a mobile communication system that improves transmission spurious characteristics without using a SAW filter, which is essentially used.

More specifically, a low pass filter (LPF) is added to the input signal (I, Q) input stages to remove baseband 8.192 MHz multiplied clock noise to improve the transmission spurious characteristics, and to improve the transmission transmission frequency. The use of Lumped LC BPFs instead of filters provides a handset for mobile communication systems that reduces the loss of transmitted signals and reduces amplifier current consumption.

The present invention for achieving the above object,

In the mobile communication terminal for performing QPSK modulation of the IF baseband signal processed by the baseband signal processor, up-converting to a high frequency, and amplifying and outputting the same;

A low pass filter for low frequency filtering the IF baseband signal to remove a multiplication frequency of 8.192 MHz added by the baseband signal processor;

A QPSK modulator for QPSK modulating the baseband signal filtered by the low pass filter;

An LC band filter for band filtering the intermediate frequency IF output from the QPSK modulator and passing only a required frequency band;

An automatic gain control unit controlling a gain of a transmission signal through the LC band filter;

A frequency upconverter for upconverting the transmission signal output from the automatic gain control unit to a high frequency;

A high frequency band filter for filtering a high frequency output from the frequency up-converter into a set band;

A preamplifier for preamplifying the signal output from the high frequency band filter;

A drive amplifier for amplifying the output signal of the preamplifier to a predetermined level;

And a final amplifier for finally amplifying the output signal of the drive amplifier and outputting it as a transmission signal.

Hereinafter, described in detail with reference to the accompanying drawings, preferred embodiments of the present invention according to the technical spirit as described above.

2 is a diagram illustrating a configuration of a transmitting end of a mobile communication terminal according to the present invention.

Here, reference numeral 101 denotes a low pass filter for low-pass filtering the IF baseband signal to remove a multiplication frequency of 8.192 MHz added by a front end baseband signal processor, and reference numeral 102 denotes a low pass filter for filtering by the low pass filter 101. A QPSK modulator for QPSK modulating the baseband signal is indicated, and reference numeral 103 denotes an LC band filter for bandpassing the required frequency band by band filtering the intermediate frequency IF output from the QPSK modulator 102.

In addition, reference numeral 104 denotes an automatic gain control unit for controlling the gain of the transmission signal through the LC band filter 103, and reference numeral 105 denotes an upconversion of the transmission signal output from the automatic gain control unit 104 to a high frequency. A frequency up-converter is indicated, and reference numeral 106 denotes a high-frequency band filter for filtering the high frequency output from the frequency up-converter 105 to a set band.

In addition, reference numeral 107 denotes a preamplifier for preamplifying the signal output from the high frequency band filter 106, reference numeral 108 denotes a drive amplifier for amplifying the output signal of the preamplifier 107 to a predetermined level, Reference numeral 109 denotes a final amplifier which finally amplifies the output signal of the drive amplifier 108 and outputs it as a transmission signal.

The mobile communication terminal according to the present invention configured as described above performs low pass filtering on the IF baseband signal transmitted from the front end baseband signal processing unit in the low pass filter unit 101 to remove the multiplication frequency of 8.192 MHz. Here, it should be understood that the multiplication frequency of 8.192MHz means a frequency corresponding to a multiplication (integer multiple) of 8.192MHz.

That is, the low pass filter unit 101 includes a first low pass filter 101a for low pass filtering an I signal among baseband signals, and a second low pass filter 101b for low pass filtering a Q signal. Each of the second low pass filters 101a and 101b is composed of a third-order Chebyshev low pass filter made of inductor L1 capacitors C1 and C2, as shown in FIG. 3, and has a multiplication of 8.192 MHz included in the input baseband signal. Eliminate spurious by eliminating frequencies. Here, the values of the inductor L1 and the capacitors C1 and C2 constituting the 3rd order Chebyshev low pass filter are determined by the device value calculation method so that the 3rd order Chebyshev low pass filter can remove the multiplication frequency of 8.192 MHz. It is important to understand that the value is determined.

The spurious-free signal is input to the QPSK modulator 102, and the QPSK modulator 102 performs QPSK modulation on the baseband signal filtered by the low pass filter 101.

In addition, the LC band filter 103 band filters the intermediate frequency IF output from the QPSK modulator 102 using an LC band filter implemented as shown in FIG. 4 to pass only the required frequency band (140 MHz). Here, it should be understood that the LC value constituting the LC band filter is determined by the device value calculation method so that the LC band filter passes only the required frequency band (140 MHz).

5 shows a characteristic curve of the LC band filter 103.

In addition, the automatic gain control unit 104 controls the gain of the transmission signal through the LC band filter 103 according to the gain set by adding the power control information transmitted from the base station and the RSSI obtained from the received signal.

The gain-controlled transmission signal is input to the frequency up converter 105, and the frequency up converter 105 up-converts the transmission signal output from the automatic gain control unit 104 to a high frequency. 106 filters the high frequency output from the frequency up-converter 105 to a set band (2315 MHz).

The preamplifier 107 preamplifies the signal output from the high frequency band filter 106, the driver amplifier 108 amplifies the output signal of the preamplifier 107 to a predetermined level, and the final amplifier 109. ) Amplifies the output signal of the drive amplifier 108 and outputs it as a transmission signal.

FIG. 6 is an RF output spectrum for explaining the characteristics of the low pass filter applied to the present invention. FIG. 6A is an RF output spectrum when a low pass filter is not used at a transmission signal input as in the prior art. As in the present invention, the RF output spectrum when the low pass filter is used at the input signal is shown.

According to the above-described "terminal of the mobile communication system", the baseband 8.192MHz clock noise can be eliminated by adding the I, Q low pass filter in front of the QPSK modulator, so that the transmission spurious characteristic can be improved. There is an advantage to that.

In addition, by using an LC band filter instead of the conventional TX IF SAW filter, path loss can be compensated for, thereby reducing the additional power of the amplifier.

In addition, in order to remove the transmission spurious, conventionally, a plurality of band filters are used for the RF stage and a SAW filter is used for the IF stage. However, the present invention uses only one RF band filter and an LC filter. This reduces the overall cost and reduces the circuit components, thereby reducing the circuit size.

Claims (3)

In the mobile communication terminal for performing QPSK modulation of the IF baseband signal processed by the baseband signal processor, up-converting to a high frequency, and amplifying and outputting the same; A low pass filter for low frequency filtering the IF baseband signal to remove a multiplication frequency of 8.192 MHz added by the baseband signal processor; A QPSK modulator for QPSK modulating the baseband signal filtered by the low pass filter; An LC band filter for band filtering the intermediate frequency IF output from the QPSK modulator and passing only a required frequency band; An automatic gain control unit controlling a gain of a transmission signal through the LC band filter; A frequency upconverter for upconverting the transmission signal output from the automatic gain control unit to a high frequency; A high frequency band filter for filtering a high frequency output from the frequency up-converter into a set band; A preamplifier for preamplifying the signal output from the high frequency band filter; A drive amplifier for amplifying the output signal of the preamplifier to a predetermined level; And a final amplifier for finally amplifying an output signal of the drive amplifier and outputting the output signal as a transmission signal. The mobile communication apparatus of claim 1, wherein the low pass filter comprises a first low pass filter for low pass filtering an I signal in a baseband signal, and a second low pass filter for low pass filtering a Q signal in the baseband signal. The terminal of the system. 3. The terminal of claim 2, wherein each of the first and second low pass filters is a third order Chebyshev low pass filter.

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