KR100486544B1 - Signal measuring method for neighbor base stations - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wideband code division multiple access (WCDMA) system, and in particular, a downlink signal when attaching a location measurement unit (LMU) for estimating the position of a terminal to a base station. The present invention relates to a method for measuring neighboring base station signals that can more clearly receive neighboring base station signals without degrading its performance. Conventional base station signal measurement for terminal location tracking removes data because it inserts an idle period that stops the signals of all channels during the forward signal transmission to measure the weak signal of the neighboring base station while removing the strong signal of the current base station. There is a high risk that there is a problem that degrades the performance of the forward transmission. In view of the above problems, the present invention receives a sum of a forward continuous signal of a base station to which an LMU is attached and a signal of a neighboring base station from the LMU, removes an estimated signal of the base station to which the LMU is currently attached, and measures only signals from the adjacent base station By doing so, it is possible to clearly receive signals of neighboring base stations without degrading performance.

Description

SIGNAL MEASURING METHOD FOR NEIGHBOR BASE STATIONS

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wideband code division multiple access (WCDMA) system, and in particular, a downlink signal when attaching a location measurement unit (LMU) for estimating the position of a terminal to a base station. The present invention relates to a method for measuring neighboring base station signals that can more clearly receive neighboring base station signals without degrading its performance.

The WCDMA system provides a terminal location service for determining the location of the terminal. The WCDMA system measures the frame time received from the terminal and the frame difference seen from the base station by looking at the frame time difference from the adjacent base station. Measure the distance between the base station and the terminal. When the distance between the base station and the terminal is measured in three different base stations, the position of the terminal can be determined.

Therefore, in order to know the location of the terminal, the frame time difference between the base station and the terminal and the relative frame time (RTD) between the base stations are known, and a dedicated device called an LMU is used to measure the RTD between the base stations. .

The LMU may be located between base stations and attached to the base station. The application of this LMU is described on page 12 of 3GPP TS 25.923 (R4), which uses the synchronization between base stations.

In this case, the LMU is attached to the base station as an example.

1 shows a signal area between adjacent base stations, and shows three adjacent base stations 10, 20, 30. The base stations 10, 20, and 30 have respective cell regions, and the signal weakens rapidly after passing the illustrated region.

If the LMU of base station a 10 measures the signals of neighboring base station b 20 and base station c 30, this would be Da (t) + Db (t) + Dc (t), of which Da ( t) becomes larger than the remaining Db (t) and Dc (t).

As described above, the base station to which the LMU is attached measures the frame time of the neighboring base station by using the LMU. In order to measure the base station signal of the neighboring cell in the cell area where the terminal is located, an idle period of downlink signals is measured. In this case, only the base station signal of the neighboring cell is measured during this period. This is called an IPDL (Idle Period in Down Link) location measurement method. This method of IPLD measurement is described on pages 42-44 of 3GPP TS 25.214.

That is, since the signal of the base station to which the LMU is attached is so strong compared to the signal of the neighboring base stations, the time transmission for all channels of the base station to which the LMU is attached is temporarily transmitted in order to clearly receive the signals of the neighboring base stations by excluding the interference. An idle period that is stopped is created in the forward signal.

FIG. 2 illustrates an example of a forward signal including an idle period, and illustrates a forward signal in a burst mode among idle periods divided into a continuous mode and a burst mode.

As shown in the figure, a system frame number (SFN) is present in the forward signal. To measure the position of the terminal, a difference in SFN is obtained. This is a higher concept, and the LMU detects a difference in a common pilot channel (CPICH, hereinafter referred to as CPICH) in an actual physical layer, and obtains a difference in SFN from the index. do.

Bust_Start is used to specify the first burst start of the idle period, and the illustrated 256 × Bust_Start is the SFN where the first burst of the idle period starts.

Thereafter, an idle period of burst # 0 is shown, which is 256xBust_Start as above of the SFN at the beginning. Bust_Freq represents the time from the start of one burst to the start of the next burst, and 256 × Bust_Freq is the number of radio frames of the primary CPICH in one burst.

Therefore, the forward signals are interrupted in the middle, and there is a fear of data loss because the time transmission of all channels of the base station is temporarily interrupted during this idle period, and the overall performance is degraded.

In summary, in the conventional method for measuring a base station signal using an IPDL, when a signal of a base station to which an LMU is attached is Da (t), and signals of neighboring base stations are Db (t) and Dc (t), a received signal measured by the LMU The sum of R (t) is obtained by the following equation.

R (t) = Db (t) + Dc (t) + Noise

That is, the LMU measures the signals of neighboring base stations at the point in time when there is no signal of Da (t) (idle period).

As described above, the conventional base station signal measurement for terminal location tracking inserts an idle period in which all channels are stopped during forward signal transmission to measure the weak signal of the neighboring base station while removing the strong signal of the current base station. The risk of data loss is high and there is a problem of degrading the performance of forward transmission.

In view of the above problems, the present invention allows the output of the current base station to be removed from the sum of base station signals measured in the LMU without inserting an idle period during forward transmission, thereby measuring only signals from neighboring base stations without degrading forward performance. It is an object of the present invention to provide a method for measuring an adjacent base station signal that is suitable.

In order to achieve the above object, the present invention provides a method for measuring a neighbor base station signal in an LMU to measure a terminal position in a wideband code division multiplexing system. Obtaining a sum (R (t)) of the base station signals during the period of time; Generating an estimated signal value da (t) of the base station using the original digital signal Sd (t) received from the base station to which the LMU is attached, the base station internal characteristic value, and the phase of the signal; And removing the estimated signal value da (t) of the base station to which the LMU is attached from the sum R (t) of the base station signals to obtain the signal sum r (t) of neighboring base stations. It is done.

The estimated signal value da (t) of the base station to which the LMU is attached is

da (t) = Sd (t) × Ag (t) × cosw _o t

Ag is a base station characteristic value that the original digital signal Sd (t) has while passing through a wireless signal conversion unit of the base station, and cosw _o t is a phase measurement of a common pilot channel signal (CPICH). It is characterized by the phase of the obtained signal.

Hereinafter, with reference to the accompanying drawings, the present invention configured as described above will be described in detail.

Referring again to the region of the base stations of FIG. 1, the signal of the base station a 10 to which the LMU is attached is called Da (t), and the signals of the adjacent base station b 20 and the base station c 30 are respectively referred to as Db ( Let t) and Dc (t), the sum R (t) that the LMU receives the signals of the base stations that transmit a continuous forward signal is as follows.

R (t) = Da (t) + Db (t) + Dc (t) + Noise

Among them, Da (t) is a signal of a base station to which the measurement is performed, and thus the signal strength is strong, and thus Da (t) may interfere with weak signals Db (t) and Dc (t) from neighboring base stations. (t) must be removed.

Since it is difficult to receive and extract the signal transmitted from the base station to which the LMU is attached to obtain the Da (t), the original digital signal state before the forwarding signal of the base station to which the LMU is attached is converted into a signal for wireless transmission. Receives and computes this to infer Da (t).

Therefore, in the base station to which the LMU is attached, a function of transmitting an original digital signal Sd (t) to the LMU should be added. This transfer can be either wireless or wired and is independent of the base station signal measurement portion of the LMU because it is the transmission and reception of digital signals.

The LMU estimates the signal output from the base station by multiplying the internal characteristics of the base station, which may be generated when the original digital signal is received from the base station and wirelessly transmitted through the base station. The phase of the signal is measured to obtain cosw _o t and multiplied by the estimated signal value.

The signal da (t) of the base station a estimated Da (t) through the above method can be obtained by the following equation.

da (t) = base station internal characteristic value (Ag) × Sd (t) × cosw _o t

Figure 3 shows a brief configuration for an embodiment of the present invention, it will be seen that the configuration of the base station and the configuration of the LMU are interconnected as shown.

According to the configuration of the base station, the base station modem 100 for generating a forward digital signal, the forward digital signal (Sd (t)) output from the base station modem 100, and converting the digital signal into a radio signal that can be transmitted It consists of an intermediate frequency processing unit 110, a radio frequency processing unit 120, and an antenna 130 for this, it can be used to perform the calculation step of the present invention.

The LMU is also composed of the LMU function 140 for internal measurement and the intermediate frequency processor 150, the radio frequency processor 160, and the antenna 170 for receiving the signals of the base stations are necessary for the calculation step of the present invention. Can receive values.

The base station may transmit a forward original digital signal Sd (t) to the outside before the process of converting the signal into a wireless signal, and the LMU function unit 140 may receive it. Note that in the figure it may appear as a wired connection but can be connected wirelessly.

As described above, the present invention can be applied to the base station by adding a simple data output unit to the existing modem. The present invention is to change the operation part of the internal control unit without greatly changing the configuration of the LMU and the base station.

The operation of FIG. 4 calculates how the LMU function unit 140 can obtain only the signal sums of neighboring base stations from which the signal of the base station Da (t) to which it is attached is removed from the sum R (t) of all base station signals. Use blocks to explain. Although described as an operation block for easy understanding of the present invention, it should be noted that the operation steps of the present invention are clarified through this.

As shown in FIG. 4, cosw _o t can be known by measuring the phase of the CPICH signal by receiving the sum R (t) of all base station signals. By multiplying cosw _o t obtained through the CPICH estimator 200 with the Sd (t) and internal characteristic values of the base station, the estimated signal value da (t) of the base station to which the LMU is currently attached can be known. When the estimated signal value da (t) is added to the R (t) and the adder 220, the da (t) is removed from the R (t) by a phase difference to obtain r (t).

The internal characteristic value Ag of the base station means a characteristic value of the base station that Sd (t) has while passing through the intermediate frequency processing unit and the radio frequency processing unit of the base station. Available through the market, and is apparent to those skilled in the art.

The r (t) is the same as the sum of the base station signals (Db (t) + Dc (t) + noise) obtained using the conventional IPDL.

In summary, r (t) can be found as

r (t) = Da (t) + Db (t) + Dc (t) + Noise-(Sd (t) × Ag (t) × cosw _o t)

     = R (t)-da (t)

     = Db (t) + Dc (t) + Noise

Accordingly, in order to apply the present invention, first, when the continuous signal sum R (t) of all base stations is obtained, the estimated signal da (t) of the base station to which the LMU is attached is obtained, and then it is removed from the signal sum of the base stations. (R (t) -da (t))

That is, even when a continuous forward signal is being transmitted, only the sum of the signals of neighboring base stations can be obtained without leaving an idle period in which the signal is lost or damaged in the forward signal.

As described above, the present invention receives the sum of the forward continuous signal of the base station with the LMU and the signals of the neighboring base station in the LMU, and removes the estimated signal of the base station with the current LMU attached thereto to measure only the signal from the neighboring base station. By doing so, it is possible to clearly receive signals of neighboring base stations without degrading performance.

1 shows an area of base stations for measuring terminal location.

2 illustrates the placement of idle periods in a conventional forward burst mode.

3 briefly illustrates a system configuration for an embodiment of the present invention.

4 is a calculation block diagram illustrating a calculation method according to an exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: base station a 20: base station b

30: base station c 100: base station modem

110: intermediate frequency processing unit (IF) 120: radio signal processing unit (RF)

130: base station antenna 140: position measurement unit (LMU) function

150: intermediate frequency processing unit (IF) 160: radio signal processing unit (RF)

170: LMU antenna 200: common pilot channel phase estimator

210: multiplier 220: adder

Claims (3)

Obtaining a sum R (t) of the base station signal to which the LMU is attached and the adjacent base station signals; Generating an estimated signal value da (t) of the base station to which the LMU is attached; Measuring the neighboring base station signal by removing the estimated signal value da (t) from the sum of the base station signals R (t) to obtain the sum of signals r (t) of neighboring base stations. Way. The method of claim 1, wherein the estimated signal value da (t) is obtained by using the following equation. Da (t) = Sd (t) × Ag (t) × cosw _o t (Ag is a base station characteristic value that the original digital signal Sd (t) has while passing through a wireless signal conversion unit of a base station, and cosw _o t is a phase of a signal obtained by measuring a phase of a common pilot channel signal CPICH) 3. The method of claim 2, wherein the signal sum r (t) of the neighbor base stations is obtained using the following equation. R (t) = R (t)-da (t) = Da (t) + Db (t) + Dc (t) + Noise-(Sd (t) × Ag (t) × cosw _o t) (Da (t) is the signal of the base station to which the LMU is attached, and Db (t) and Dc (t) are the signals of the adjacent base stations)