KR100205047B1 - Open loop power control method in cdma cellular system - Google Patents

Abstract

The present invention relates to an open loop power control method in a Code Division Mutiple Access (CDMA) cellular system. In the CDMA cellular system, when a terminal starts a call, the base station determines the power control constants of all terminals in the cell according to the size of the cell. A first step of differently allocating every step; and a second step of transmitting, by the terminal, the number signal strength obtained by subtracting the output signal strength of the base station from the assigned power control constant value to the base station with the signal strength summed with the power control constant. By making the received signal strength of the base station constant regardless of the cell size, the received signal strength of the base station is constant in the CDMA cellular system, and the capacity of the reverse link can be increased, thereby creating an economical CDMA cellular system. It can be implemented.

Description

Open-Loop Power Control in CDM Cellular Systems

1 is a schematic configuration diagram of a CDMA cellular system for an open loop power control method of the prior art.

2 is a schematic diagram of a CDMA cellular system for an open loop power control method of the present invention.

3 is a flowchart illustrating transmission and reception signals between a terminal and a base station for implementing open loop power control.

FIG. 3a shows the signal flow for transmitting the power control constant when the originating signal, FIG. 3b is the incoming call, and FIG. 3c is the handoff.

* Explanation of symbols for main parts of the drawings

10, 20: cell A, cell B

11, 21, 12, 22: Mobile Station (MS)

15, 25: Base Station (BS)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an open loop power control method in a code division multiple access (CDMA) cellular system, and more particularly, to the reverse link from a mobile terminal (vehicle terminal or personal portable terminal) to a base station. An open loop power control method for increasing capacity.

In general, the radio link capacity in a CDMA cellular system using Spread Spectrum (SS) is based on conventional frequency division multiple access (FDMA) or time division multiple access (TDMA). Unlike the system, even if the same bandwidth (bandwidth), depending on the amount of interference (interference) included in the radio link.

Here, the general CDMA cellular system is largely composed of a supporting station and a terminal, and a certain base station (BS) is responsible for communication between a plurality of terminals in a certain cell A and cell B to provide a service.

On the other hand, the capacity of the radio link of the CDMA cellular system is larger than that of the reverse link (the radio link from the terminal to the base station).

Thus, the radio link capacity of a CDMA cellular system is determined by the capacity of the reverse link.

That is, the reverse link capacity of the CDMA system is determined according to the signal strength (ie, power) received from a plurality of terminals.

In particular, when the transmission signal strength from the link user in the cell area managed by the base station itself is equal to the reception signal strength of the base station, the capacity of the reverse link is maximum.

As such, it is necessary to control the received signal strength, i.e., power, from the terminal for determining the capacity of the reverse link.

One way to achieve this is open loop power control.

The open loop electric shock control is a method of controlling the signal strength transmitted from the terminal to control the signal received from the base station.

That is, when the terminal adjusts the output signal strength so that the sum of the received signal detail and the output signal strength in the terminal is the same, the received signal at the base station is made constant regardless of the path loss of the radio link.

At this time, the open loop power control works ideally when the path loss of the forward link and the path loss of the reverse link are the same.

In order to perform such open loop power control, the base station in the prior art has fixed the open loop power control constant in each terminal.

Here, the open loop power control constant (hereinafter, referred to as a "power control constant") refers to the sum of the received signal strength and the output signal strength in the terminal.

However, as described above, according to Qualcomm of the United States, the power control constant is a constant value of the current CDMA terminal.

An example of the conventional open loop power control according to this is as shown in FIG.

Prior to the description, (X, Y) represents the received signal strength X (dBm) and the output signal strength Y (dBm) at the location of the terminal or the base station, respectively.

Accordingly, the power control constant in the prior art is the sum of X + Y (dBm) per cell, and the sum is fixed.

That is, as shown in FIG. 1, the power control constants of the terminals 11, 12, 21, and 22 in the cell A 10 and the cell B 20 are all fixed at -73 dBm.

As an example, the terminal 11 sets the received signal strength X to -10 dBm and the output signal strength Y to -63 dBm, so that the power control constant that says the sum of the signal strengths is fixed at -73 dBm.

Of course, the same is true for the terminals 12, 21, 22 and the base stations 15, 25 as well.

An example thereof will be described in more detail as follows.

When the constant value is -73 dBm in the cell A 10 and the output signal strength is 38 dBm at the base station 15, the received signal strength is 20 dBm at the A terminal 12 having a path loss of 18 dBm (near range), and the output signal. The strength is -93 dBm, and the received signal strength at the base station 15 is -111 dBm.

Further, when the constant value is -73 dBm and the output signal strength at the base station 15 is 38 dBm, the received signal strength at the B interrupter 11 having a path loss of 48 dBm (distant) is -10 dBm, and the output signal strength. Is -63dBm, and the received signal strength at the base station 11 is -111dBm as in the A terminal 11.

Similarly, in cell B 20, the power control constant is fixed irrespective of the size of cell A 10.

However, if the power control constant is fixed irrespective of the cell size as in the present case, when the cell sizes are the same, the signal strengths received by all base stations are the same, but when the cell sizes are different, the signal strengths are different for each base station.

The base station receives the size of the cell it manages at different signal strengths even if the path loss is the same.

Therefore, even if the path loss between the terminal and the base station is the same, if the cell (or its base station) is changed, the output signal strength of the terminal is changed due to the fixed power control constant.

Therefore, the signal strength received at the base station varies from cell to cell.

The different received signal strengths for each base station not only make the operation (power control) of the system difficult, but also reduce the reverse link capacity, thereby degrading the utilization efficiency of radio resources.

Therefore, there is a need to complement the open loop power control method currently implemented in the terminal.

An object of the present invention is to provide an open loop power control method that is easy to implement while maximizing the advantages of CDMA to solve the above problems.

In order to achieve the above object, a feature of the present invention is that, when a terminal starts a call in a CDMA cellular system, the base station allocates a power control constant of every terminal in the cell differently according to the size of the cell to each cell, and the allocated power control. By receiving the received signal strength minus the power signal strength of the corresponding base station of each terminal from the constant value to the base station as the signal strength plus the power control constant, the received signal strength of the base station is made constant regardless of the cell size It is done.

In addition, it is characterized in that the open loop transmission control constant is included and transmitted in a signal message having an originating, incoming and handoff signal.

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

First, FIG. 2 shows a configuration between a base station and a terminal located at different cell sizes in a typical CDMA cellular system.

Since the configuration thereof is the same as that of the first drawing, it is omitted.

However, the power control constants of the cell A 10 and the cell B 20 only vary depending on the size of the cell.

Therefore, the received signal strength and the output signal strength for determining the power control constant are also different.

The power control constant is notified to the terminals 11, 12, 21, and 22 in its own cell area by the base stations 15 and 25, and each terminal has a strength obtained by subtracting the signal strength received from its base station from this constant value. Send a signal to

Accordingly, as shown in FIG. 2, the power control constant changes to -73 dBm for the cell A 10 and -53 dBm for the cell B 20 (the size of the cell B is larger than the size of the cell A). Relatively large).

In other words, the power control constant changes according to the output signal strength of the base station for each cell.

This is because the base station changes the power control constant so that the larger the cell size, the larger the power control constant.

Referring to the embodiment, first, if the power control constant is set to -73 dBm in the cell A (10), in the case of the A terminal (nearby) 12, the path loss is 18 dBm as in the above-described conditions, and the base station 15 Since the output signal strength at A1) is 38 dBm, the received signal strength at the A terminal 12 is 20 dBm.

The output signal strength of the terminal A 12 is -93 dBm since the power control constant (= received signal strength + output signal strength) is -73 dBm.

Therefore, the received signal strength at the base station is -111 dBm.

In the case of the B terminal (remote) 11 located in the cell A 10, since the path loss with the base station 15 is 48 dBm, the received signal strength at the base station 15 is -111 dBm as in the above process.

On the other hand, in the cell B 20, which is different in size from the cell A 10, the power control constant is changed to -53 dBm.

Here, the path loss between the base station 25 and the A terminal 22 located at a short distance is 18 dBm, and the path loss between the B terminal 21 located at a far distance is 48 dBm.

As an example, when the output signal strength at the base station 25 is 58 dBm, the received signal strength of the terminal A 22 is 40 dBm, and thus the output signal strength of the terminal A 22 is -93 dBm. .

Therefore, the received signal strength of the base station 25 is -111 dBm, similarly to the received signal strength of the cell A 10.

In this way, the received signal strength at all base stations is constant.

3 illustrates an example of transmitting the power control constant in a signal message, and may be broadly divided into a case of a call signal (a), an incoming signal (b), and a handoff (c).

First, referring to the case of the outgoing signal a, the terminal MS is notified of the power control constant from its base station BS when the call starts.

The power control constant at this time is included as a parameter in the signal message for the existing call processing.

As shown in the signaling message, when the terminal sends an origination message (Origination Msg.) To the base station, the base station transmits a response message (BS ack order) thereto.

At this time, the response message is the first response message from the base station, and the base station notifies the terminal by including the power control constant as one parameter in the response message.

Next, also in the case of an incoming call (b), when the base station receives the paging message (Paging Msg.) From the terminal, the base station transmits a paging response message (Page_resp_Msg.) To the terminal station.

Accordingly, after receiving the call response message from the base station, the terminal station notifies the base station by including the power control constant as one parameter in the first response message (BS ack order).

In case of the handoff (c), the base station measures the received field strength received from the terminal (Plt_strength_Meas.) And includes the power control constant of the base station of the destination cell as one parameter in the direct handoff message (HO_direct_Msg.). Is notified to the terminal.

As described above, the present invention allows open-loop power control to be performed at different constant values for each cell, thereby allowing all base stations of the CDMA cellular system to receive the same signal size.

Therefore, not only can the efficiency of radio resources be increased (that is, the capacity of the reverse link is increased), but also an economical CDMA system can be implemented.

Claims (2)

In the CDMA cellular system, when the terminal starts a call, the base station assigns a power control constant of every terminal in the cell differently according to the size of the cell for each cell; Performing a second step of transmitting, by the terminal, the received signal strength obtained by subtracting the output signal strength of the corresponding base station from the assigned power control constant value to the base station with the signal strength summed with the power control constant; A method of controlling open loop power in a CDMA cellular system, characterized in that the received signal strength of the base station is constant. 2. The CDA cellular system according to claim 1, wherein the second step includes transmitting the open loop transmission control constant in a signal message including an origination signal, an incoming signal, and a handoff signal. Open-loop power control method