KR20010084686A - Frequency synchronizing system and method for hand-off between adjacent cells having different freqency - Google Patents

Abstract

PURPOSE: A frequency synchronous system for hand-off between adjacent cells having different frequency and a method thereof are provided to realize a soft hand-off without converting a frequency and a call disconnect by simultaneously converting a plurality of frequency channels into a baseband. CONSTITUTION: A local oscillating frequency generator(510) generates the first local oscillating frequency. A down converter(520) mixes a radio frequency with the first local oscillating frequency for downward converting a radio frequency signal into a baseband signal. An amplifier(530) amplifies the down-converted baseband signal. A local oscillating frequency generator(540) generates the second local oscillating frequency. A down converter(550) mixes the radio frequency with the second local oscillating frequency for downward converting the radio frequency signal into the baseband signal. An amplifier(560) amplifies the down-converted baseband signal. An adder(570) adds the amplified baseband signals.

Description

FREQUENCY SYNCHRONIZING SYSTEM AND METHOD FOR HAND-OFF BETWEEN ADJACENT CELLS HAVING DIFFERENT FREQENCY}

The present invention is currently in use wireless subscriber network (WLL), broadband wireless subscriber network (B-WLL), radio frequency network (TRS), mobile telephone network (Cellullar), personal mobile communication network (PCS), intelligent transportation network (ITS), foreign countries Code division multiplexing in wireless communication networks including other mobile phone networks in use in next-generation mobile communication networks such as IMT-2000 (International Mobile Telecommunication) and Universal Mobile Telecommunication Service (UMTS) The present invention relates to a frequency synchronization system for handoff between adjacent cells having different frequencies using a code division multiple access (CDMA) scheme, and more particularly, to a baseband of a plurality of frequency channels simultaneously at the receiving end of a mobile telephone terminal. A frequency synchronization system and method for handoff between adjacent cells having different frequencies that can be converted are provided.

Generally, in a cellular mobile communication system using CDMA mobile communication, the process of channel shifting by a mobile station to an adjacent cell is called handoff, which is different from handoff using the same frequency. There is a handoff using frequency.

In the IS-95 using the CDMA scheme, the neighboring cells use the same frequency, but independent fingers are used by different offsets of the Pseudo Noise (PN) sequences. A seamless handoff is performed through soft handoff, which is a process of tracking each pseudonoise sequence and acquiring synchronization thereto.

1 is a schematic diagram of a terminal receiving apparatus of a general mobile phone, and includes a down converter 110, a mixer 120, a local oscillator 130, a low pass filter 140, and a demodulator 150. do.

Referring to the operation of the receiver of a general mobile phone terminal having such a structure is as follows.

The high frequency signal received from the antenna is down-converted to the baseband signal through the down converter 110, wherein the down converter 110 mixes the existing high frequency signal received from the local oscillator 130 to the baseband signal. Downconvert to. The down-converted baseband signal is filtered through the low pass filter 140 to remove the noise and then transferred to the demodulator 150.

CDMA mobile communication uses a random number to randomize a signal to be transmitted. At this time, if the order of the given pseudo random number is known correctly, the signal to be delivered can be extracted accurately.

Since each base station uses different pseudo random number in cellular network, communication information with currently connected base station is applied by extracting the corresponding pseudo random number, and signal of other base station is interpreted as noise signal only by this pseudo random number. do. Communication is possible only when the pseudo-noise sequence is correctly synchronized.

On the other hand, since the general method of synchronization uses a method of finding the optimum synchronization by continuously changing the pseudonoise sequence offset, it is necessary to apply all possible offsets for synchronization, and this requires a basic operation time.

Of course, in order to speed up the synchronization algorithm, a method of verifying a plurality of pseudonoise sequence offset assumptions by adding additional hardware, or implementing a matched filter has been proposed. However, there is a practical problem when the hardware is increased more than necessary or the pseudo noise sequence is long.

In the current IS-95, since neighboring cells use the same frequency, information on neighboring cells as well as the cell to which the current call is connected are input at the modem input. The searcher and the fingers that make up the CDMA modem independently track and demodulate these signals. In this case, it is possible to continuously process the input signal without disconnection of the signal and have enough time for synchronization, so that even if the time taken for synchronization is long, there are almost no problems in practical use.

2A is an explanatory diagram of a radio frequency reception process of a conventional mobile phone terminal, and FIG. 2B is an explanatory diagram of a baseband signal processing process of a conventional mobile phone terminal.

If Figures 2a and FIG. 2b, is converted into a baseband signal as shown in the center frequency of the Figure 2a f ₁ and the input signals s _1, it s ₂ is a 2b having a f _2, the center frequency of the signal s ₁ ' Becomes f ₁ and the center frequency of the local oscillator LO also becomes f ₁ , so the signal s ₁ ′ is converted to a baseband signal.

In addition, when signal s ₂ 'is converted to a signal having a center frequency of f ₂ -f ₁ , the baseband signal passes through a low pass filter, filtering out the signal s ₂ ' out of the passband and leaving only the original signal s ₁ ′. .

That is, if the center frequency of the cell to be handed off has the same value, the signal of the current cell and the cell to be handed off overlaps and is transmitted to the modem. If the frequency has a different value, the signal is not transmitted to the modem. . In this case, in order to perform the handoff, the process of changing the current local oscillator LO from f ₁ to f ₂ and searching for synchronization again must be performed.

Therefore, when changing the frequency of the frequency synthesizer, it takes a certain time for the frequency synthesizer to lock to a new frequency. In this case, the output frequency according to the time of the frequency synthesizer has a characteristic as shown in FIG.

3 is a characteristic diagram of local oscillation frequency conversion used for frequency synthesis of a conventional mobile telephone terminal.

That is, it takes about t ₁ to stabilize by changing from f ₁ to f ₂ , and it takes about t ₂ to change from f ₂ to f ₁ . Frequency synthesizers with fast locking times and low frequency values must set the polarity of their loop filter or voltage controlled oscillator (VCO) differently. Frequency synthesizers that can make frequency transitions in a short time are not easy to design, so they must be allocated some amount of transition time.

On the other hand, when this time is long, the probability of disconnection increases because a signal synchronized to the original channel loses the synchronization signal.

If the neighboring cell cannot use the different frequency to handoff to the current frequency, the neighboring cell should search for the frequency to be handed off and perform synchronization with it. This is because changing the local oscillation frequency of the terminal back to the desired frequency and searching for the desired signal and resetting the synchronization according to this is because the time taken for handoff is greatly increased compared to the case of using the same frequency.

At this time, if this time increases more than necessary, there is a possibility that the pseudo noise sequence offset of the channel to which the current call is connected may be lost. This problem can be solved by connecting hardware in parallel so that multiple frequencies can be demodulated at the same time. However, since hardware is needed as many as desired frequency channels, it is not suitable for practical use using low power consumption terminal and minimum hardware. not.

Therefore, in order to hand off a channel of a mobile telephone terminal using a conventional frequency conversion and synthesis device as described above to another channel, it is necessary to realize the synchronization by moving the center frequency to another channel. There was a problem that the call quality was deteriorated even though it was disconnected and attempted to realize synchronization with another channel.

The present invention has been made to solve the above problems, and in implementing a receiving end of a mobile telephone terminal in a wireless communication system such as a cellular mobile communication system, PCS, IMT-2000, a plurality of frequency channels as a baseband It is an object of the present invention to provide a frequency synchronization system and a method for realizing a soft handoff without the need for frequency conversion and by disconnection by synchronizing simultaneously.

1 is a configuration diagram of a terminal receiver of a general mobile telephone.

2A is an explanatory diagram of a radio frequency reception process of a conventional mobile telephone terminal.

2B is an explanatory diagram for a baseband signal processing procedure of a conventional mobile telephone terminal.

3 is a characteristic diagram for conversion of local oscillation frequency used for frequency synthesis of a conventional mobile telephone terminal.

4 is an explanatory diagram of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention;

5 is a diagram illustrating an embodiment of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

6 is another embodiment configuration diagram of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

7A and 7B are diagrams illustrating output characteristics of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

* Explanation of symbols for the main parts of the drawings

510, 540, 610, 620: Local oscillation frequency generator

520, 550, 690: downconverter

530, 560, 640, 660, 670: Amplifier

670, 680; adder

630, 650: multiplier

The present invention for achieving the above object, in a frequency synchronization system for handoff between adjacent cells having different frequencies in a wireless communication system, for generating the first and second local oscillation frequency of the channel to be handed off A frequency generating means; in order to maintain a current communication channel, the first local oscillation frequency is mixed with a radio frequency of a current channel, down-converted to a baseband signal, synchronized to a pseudo noise code, and amplified down-converted baseband signal Synchronizing means for outputting; In order to maintain the current communication channel between adjacent cells having different frequencies for handoff without disconnecting the call, the second local oscillation frequency is mixed with the radio frequency and down-converted to a baseband signal to be synchronized with a pseudo noise code. Variable synchronization means for amplifying and outputting the synchronized baseband signal; And adding means for adding baseband signals synchronized by the synchronization means and the variable synchronization means to output to the demodulation stage.

In addition, the present invention provides a frequency synchronization system for handoff between adjacent cells having different frequencies in a wireless communication system, comprising: frequency generating means for generating first to fourth local oscillation frequencies of a channel to be handed off; Amplifying means for amplifying the first local oscillation frequency; First frequency mixing means for mixing the first and third local oscillation frequencies, amplifying and outputting the mixed frequencies for handoff without interruption of a call by maintaining a current call channel between adjacent cells having different frequencies. ; Second frequency mixing means for mixing the second and fourth local oscillation frequencies, amplifying the mixed frequencies, and outputting the same to maintain a current communication channel between adjacent cells having different frequencies for handoff without disconnection; ; Adding means for adding frequencies output from said first and second frequency mixing means and frequencies amplified by said amplifying means; And synchronizing means for mixing the frequency transmitted from the adding means and a plurality of radio frequencies received from the base station, down converting the baseband signal into a baseband signal, and synchronizing the pseudo noise code.

In addition, the present invention, in the frequency synchronization method for handoff between adjacent cells having different frequencies applied to the wireless communication system, the hand without disconnection of the call by maintaining the current communication channel between adjacent cells having different frequencies A first step of generating a local oscillation frequency of a channel to be handed off for off; A second step of mixing the local oscillation frequency with a radio frequency of a current channel; And a third step of downconverting the mixed frequency of the same channel into a baseband signal and synchronizing to a pseudo noise code.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is an explanatory diagram of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

As shown in Fig. 4, the present invention is intended to synchronize this signal by mixing the signal frequency of the channel to be handed off with the input signal. At this time, since signals of the signal band to be handed off are input together with the modem, when the offsets of the pseudo noise sequences are different, the adjacent channels are recognized as the same channel.

If the local oscillation frequency 1 (LO frequency1) is called f ₁ of FIG. 3 and the local oscillation frequency 2 (LO frequency2) is f ₂ of FIG. 3, LO1 having f ₁ and LO2 having f ₂ are mixed to the down converter. Supply. Accordingly, the waveform v of the baseband signal passed through the low pass filter is expressed by Equation 1 below.

Here, by, t ₃ gradually away from LO1 and t _4, mixed by gradually increasing the LO2, and up to the time t ₅ the time point reduces the size of the LO1, as illustrated in the fourth mixing ratio is also in accordance with the time of the two signals t ₆ Make it zero at this point. From t ₃ , the modem is input and mixed with the s ₂ signal. The modem performs signal processing to acquire synchronization from a newly input signal in addition to the current signal. In this case, since the handoff is performed after the synchronization of the adjacent channel is completely acquired, the soft handoff can be performed even on different frequency channels.

As described above, when the local oscillation frequencies (LO1 and LO2) are mixed, other local components such as duplexers, LNA (Local Numbering Area), AGC (Automatic Gain Control), Soft handoff can be achieved without any additional hardware changes, such as filters and modems.

Specific embodiments of such a circuit are shown in FIGS. 5 and 6.

5 is a configuration diagram of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

As shown in FIG. 5, the frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention includes a first local oscillation frequency. Local oscillation frequency generating unit 510 for generating a radio frequency and the first local oscillation frequency And a down converter 520 for downconverting the radio frequency signal to a baseband signal, an amplifier 530 for amplifying the baseband signal downconverted by the downconverter 520, and a second local oscillation frequency. Local oscillation frequency generator 540 for generating a, and the radio frequency and the second local oscillation frequency And a down converter 550 for downconverting the radio frequency signal into a baseband signal, an amplifier 560 for amplifying the baseband signal downconverted by the down converter 550, and amplifiers 530 and 560. And an adder 570 for adding baseband signals amplified by the same.

First, the down converter 520 is a radio frequency signal received from the base station and the first local oscillation frequency transmitted from the local oscillation frequency generator 510 And are down-converted to the baseband signal, and then the down-converted baseband signal is amplified by the amplifier 530.

Similarly, the downconverter 550 also receives the radio frequency signal received from the base station and the second local oscillation frequency transmitted from the local oscillation frequency generator 540. Are down-converted to the baseband signal by mixing, and then the down-converted baseband signal is amplified by the amplifier 560.

As such, the baseband signals transmitted from the amplifiers 530 and 560 are output through the adder 570.

As described above, in the frequency synchronization system for different adjacent cells according to an embodiment of the present invention, two local oscillation frequency generators 610 and 620 and two multipliers 630 and 650 respectively share a common input signal. Convert the signal to baseband using the LOs of ₁ and f ₂ . In this case, when the handoff is not performed, there is almost no increase in power since only one local oscillation frequency generator and a multiplier are used. Here's how to make less hardware added:

6 is a diagram illustrating another embodiment of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

As shown in FIG. 6, the frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention includes a third local oscillation frequency. And fourth local oscillation frequency Local oscillation frequency generator 610 and a fifth local oscillation frequency for generating a And sixth local oscillation frequency Local oscillation frequency generator 620 and a third local oscillation frequency for generating a And fifth local oscillation frequency A multiplier 630 for multiplying, an amplifier 640 for amplifying a frequency multiplied by multiplier 630, and a fourth local oscillation frequency; And sixth local oscillation frequency A multiplier 650 for multiplying, an amplifier 660 for amplifying a frequency multiplied by multiplier 650, and a third local oscillation frequency; An amplifier 670 for amplifying a signal, an adder 680 for adding frequencies amplified through the amplifiers 640 and 660 and a frequency amplified through the amplifier 670, a frequency and a base station transmitted from the adder 680. And a down converter 690 for down-converting the mixed radio frequency signal into a baseband signal by mixing the radio frequency signals received from the baseband signal.

First, the third local oscillation frequency transmitted from the local oscillation frequency generator 610 And the fifth local oscillation frequency transmitted from the local oscillation frequency generator 620. Is transmitted to the multiplier 630, and the frequency multiplied by the multiplier 630 is amplified by the amplifier 640.

Similarly, the fourth local oscillation frequency transmitted from the local oscillation frequency generator 610 And the sixth local oscillation frequency transmitted from the local oscillation frequency generator 620. The frequency multiplied by the degree multiplier 650 and multiplied by the multiplier 650 is amplified by the amplifier 660.

At this time, the third local oscillation frequency transmitted from the local oscillation frequency generator 610. Is amplified by amplifier 670.

The frequencies delivered from amplifiers 640, 660 and 670 are then added via adder 680 and passed to downconverter 690.

Here, the downconverter 690 mixes the frequencies transmitted from the adder 680 and the radio frequency signal received from the base station to downconvert the mixed signal into a baseband signal.

On the other hand, as a method of making the added hardware smaller, as shown in FIG. 6, the frequency synthesizer is configured to synthesize two frequencies rather than to synthesize the LO signal into a single frequency.

In this case, the local oscillation frequency generator 610 is composed of a voltage-controlled oscillator in one unit, and the phases of the I (phase) and Q (quadrature) phases are based on the LO output so that the phases differ by 90 degrees. In addition, the desired frequency difference By using the additional local oscillation frequency generator 620 generates two frequencies of w ₁ and w ₂ together at the output.

The upper side band signal and lower side band signal components appearing in general modulation appear only depending on the phase of the I and Q signals. In Figure 6 is the output of the two frequency synthesizer Wow On each of the two outputs of Wow Multiplying and sum this, the output signal is as shown in [Equation 2].

In this case, the difference between the low frequency channels that the local oscillation frequency generator 620 can configure as a frequency synthesizer. Since it generates only, a method such as DDS (Direct Digital Synthesis) is used without the need for using a complex frequency synthesizer such as the local oscillation frequency generator 610.

7A and 7B are diagrams illustrating output characteristics of a frequency synchronization system for handoff between adjacent cells having different frequencies according to the present invention.

7A and 7B illustrate a process of converting a signal of a radio frequency band into a baseband signal using the method proposed in FIGS. 5 and 6. In this case, the two frequency components s ₁ and s ₂ are converted into s ₁ '' and s ₂ '', respectively. s ₁ ″ is the same as s ₁ ′ in FIGS. 2A and 2B, but s ₂ ″ is converted to a signal in baseband unlike FIGS. 2A and 2B.

In this way, the mixed signal allows the modem to detect more noise signals than the original signal. In order to maintain the connection with the original call channel, it is necessary to detect and synchronize the signals of the adjacent cells while appropriately adjusting the size of the mixed signals.

Therefore, the mixing ratio is adjusted by the amplification ratio (adjusting A and B) of the amplifier as shown in FIG. In the actual implementation, rather than using a separate amplifier, the method of adjusting the gain in the downconverter is used, and the method of connecting the current output terminal with an adder as it is.

As in FIG. 6, the gain of the frequency synthesizer is adjusted by the amplifiers A and B, and the mixing ratio of s ₁ and s ₂ is determined.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have knowledge.

The present invention as described above, in the IS-95 system of the DS (Direct Sequence) CDMA mobile communication standard currently operating in the first inter-frequency handoff method, there is an effect that can be implemented by handoff to another frequency.

Second, since the frequency synthesizer does not need to move the center frequency to the place where the handoff is to be handed off in a short time, the structure of the frequency synthesizer of the terminal is simplified.

Third, the terminal with the built-in inter-frequency handoff function has the effect of minimizing the call disconnection even during a hard handoff that requires frequency conversion.

Finally, the IMT-2000 system, which requires high frequency data communication by requiring inter-frequency handoff, has the effect of making inter-frequency handoff into a high performance and high quality terminal using minimal hardware.

Claims (4)

A frequency synchronization system for handoff between adjacent cells having different frequencies in a wireless communication system, Frequency generating means for generating first and second local oscillation frequencies of a channel to be handed off; In order to maintain the current call channel, the first local oscillation frequency is mixed with the radio frequency of the current channel, down-converted to a baseband signal, synchronized to a pseudo noise code, and amplified and outputted by a down-converted baseband signal. Way; In order to maintain the current communication channel between adjacent cells having different frequencies for handoff without disconnecting the call, the second local oscillation frequency is mixed with the radio frequency and down-converted to a baseband signal to be synchronized with a pseudo noise code. Variable synchronization means for amplifying and outputting the synchronized baseband signal; And Addition means for adding baseband signals synchronized by the synchronization means and the variable synchronization means to output to a demodulation stage; Frequency synchronization system for handoff between adjacent cells having a different frequency comprising a. The method of claim 1, The synchronization means and the variable synchronization means, Different frequencies, characterized in that the variable synchronization means are used only when the signal of the adjacent cell is detected and synchronized while adjusting the size of the mixed signal in order to maintain the connection with the current call channel. A frequency synchronization system for handoff between adjacent cells having a. A frequency synchronization system for handoff between adjacent cells having different frequencies in a wireless communication system, Frequency generating means for generating first to fourth local oscillation frequencies of a channel to be handed off; Amplifying means for amplifying the first local oscillation frequency; First frequency mixing means for mixing the first and third local oscillation frequencies, amplifying and outputting the mixed frequencies for handoff without interruption of a call by maintaining a current call channel between adjacent cells having different frequencies. ; Second frequency mixing means for mixing the second and fourth local oscillation frequencies, amplifying the mixed frequencies, and outputting the same to maintain a current communication channel between adjacent cells having different frequencies for handoff without disconnection; ; Adding means for adding frequencies output from said first and second frequency mixing means and frequencies amplified by said amplifying means; And Synchronizing means for mixing the frequency transmitted from the adding means and a plurality of radio frequencies received from the base station, down-converting the baseband signal to synchronize to a pseudo noise code Frequency synchronization system for handoff between adjacent cells having a different frequency comprising a. A frequency synchronization method for handoff between adjacent cells having different frequencies applied to a wireless communication system, A first step of generating a local oscillation frequency of a channel to be handed off for a handoff without disconnection of a call by maintaining a current call channel between adjacent cells having different frequencies; A second step of mixing the local oscillation frequency with a radio frequency of a current channel; And A third step of down-converting the mixed same channel frequency into a baseband signal and synchronizing to a pseudo noise code; Frequency synchronization method for handoff between adjacent cells having different frequencies comprising a.