FI97926C - Procedure for adjusting transmitter power and cellular radio systems - Google Patents

Description

97926

A method for adjusting the transmission power and a cellular radio system

The invention relates to a method for controlling transmission power in a cellular radio system comprising at least one base station in each cell communicating with subscriber terminals in its area, wherein the base station measures the power level of a signal received from the terminals and the terminal measures the input power level of the input from the base station.

It is typical of the cellular radio environment that the propagation conditions of radio waves are constantly changing. In the signal received by both the subscriber terminal and the base station, there is a constant variation, i.e. fading, as a function of time and place. Two different types of phenomena can be distinguished in signal fading. Fading can be either fast or slow and usually both phenomena occur simultaneously.

The rapid fading of the signal is due to the multipath propagation typical of the cellular radio environment, in which the signal travels several different paths between the transmitter and the receiver. The signal components arriving at the receiver from different paths are summed at the receiver and, depending on the phase differences between the signal components, they either amplify or attenuate each other. Signal level can vary considerably, up to tens of decibels, already less than half the wavelength of the way.

The slow fading of the signal, in turn, is due to the fact that the radio path has a variable number of additional attenuation factors, such as terrain obstacles or buildings. The effect of slow fading on the signal is, as the name implies, an order of magnitude slower variation in signal strength than fast fading, which produces a slow fading envelope of 2 n 7 r nr ^ f. i.

around strong power fluctuations.

Due to the above-mentioned constant variation in the strength of the received signal, in particular the transmission power used by the subscriber terminal must be constantly monitored and efforts made to adjust it to suit at any given time. The purpose of the power control is to keep the transmission power of the device as low as possible, however, with sufficient connection quality so that the signal does not interfere with other connections and so that, in particular, the power consumption 10 of the portable terminal is low.

Transmission power control is generally based on monitoring the power of the received signal at the receiver. In general, the aim is to adjust the transmission power so that the average variation of the signal level caused by the slow fading can be compensated because the variations caused by the fast fading occur too fast to be able to react to them.

However, the connection effect of fast and slow fading causes problems in power control, as it is difficult to obtain 20 reliable measurement results that would indicate attenuation caused by slow fading alone, because fast fading causes constant variation in the measurement results. Until now, a rather long measurement time has been required, during which the measurement results made are averaged, whereby the variations caused by the rapid fading can be eliminated from the measurement results.

It is already known to perform power control of a terminal, for example, by the base station measuring the power level received from the terminal by averaging it for a given time, and based on this processed measurement result and certain quality parameters, send a power control command to the terminal. The measurements made by the terminal are used to adjust the transmission power of the base station. The method described above is used, for example, in the European 35 digital mobile telephone network in GSM. The power control of the GSM system is described in more detail, for example, in M. Mouly, M. Pautet: The GSM System for Mobile Communications, 1992, pp. 342-346, which is incorporated herein by reference.

In another known way of performing power control of a terminal, the terminal itself adjusts its transmission power based on the signal power received from the base station, in addition to which the base station measures the power received from the terminal and sends power control commands to the terminal. This method is described, for example, in EIA / TIA Interim Standard: Mobile Station-Base Station

Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular System, TIA / EIA / IS-95, July 1993.

However, the problem with both of the above-mentioned methods is the same that it has already been mentioned that if reliable power control parameters are desired, the measurement results must be averaged over a relatively long period of time.

It is therefore an object of the present invention to provide a power control method by means of which the power control parameters 20 can be calculated quickly and the effect of fast fading on the measurement results can be reduced without a long averaging time.

This is achieved by a method of the type described in the introduction, characterized in that the base station 25 compares the measurement results transmitted by the terminal with its own measurement results, and that the base station adjusts the transmission power of the terminal as well as its own transmission power based on the comparison of measurement results.

The invention further relates to a cellular radio system comprising at least one base station in each cell communicating with subscriber terminals in its area, the base station having means for measuring the power level of a signal received from the terminals, and the terminal having means for measuring the power level of the signal received from the base station 35; means for reporting 4 970 ^ / - * * to transmit the measurement results to the base station. The cellular radio system according to the invention is characterized in that the base station has means for comparing the measurement results transmitted by the terminal with its own measurement results, and the means 5 adjust the transmission power of the terminal as well as its own transmission power based on the comparison of measurement results.

With the method according to the invention, the disadvantages of the previous methods can be largely avoided by eliminating the effect of rapid fading in the measurement results. The power control-10 parameters are obtained faster than previously possible, because in the method according to the invention the average winning time can be shortened. With the method according to the invention, it is possible to adjust both the transmission power of the terminal and also the transmission power used by the base station.

The invention will now be described in more detail with reference to the examples according to the accompanying drawings, in which Figure 1 illustrates an example of fast and slow fading, Figure 2 illustrates a cellular radio system in which the method according to the invention can be applied. the structure of a terminal of the radio system by means of a block diagram.

Thus, Figure 1 illustrates an example of fast and slow fading. The figure shows the received signal so that the horizontal axis has time and the vertical axis has the power level of the received signal. The power level in the receiver varies continuously, and the rapid deep fading of the power level 10 represents a fast fading, which is thus due to the multipath propagation of the signal components. The average power level 11 of the signal also varies slowly, and this is thus called slow fading due to the attenuation factors 97926 5 present in the radio path. The purpose of the power control is to compensate for the variation in power level caused by the slow attenuation in particular.

In the following, the method according to the invention will be described using the power control of the terminal as an example.

Accordingly, the transmission power used by the base station can also be adjusted by the method according to the invention.

Figure 2 illustrates a part of a cellular radio system in which the method according to the invention can be applied. The figure shows a base station 20 serving its own coverage area. The base station is connected by a transmission link 26 to a base station controller 23. The transmission link 26 is implemented by known methods such as transmission lines or a radio link. The travel station 15 can also act as a base station controller 23. The base station controller 23 controls the operation of the base station. In the situation shown in the figure, there are two subscriber terminals 21, 22 in the coverage area of the base station, to which the base station is in two-way communication 24, 25.

The subscriber terminals 21, 22 continuously measure the strength of the signal 24, 25 received from the base station at given intervals 20, and report the measurement results to the base station using known methods, such as control channels. For example, in the digital GSM system, the terminals report the measurement result 480 to the base station every 25 ms. Correspondingly, the base station 20 continuously measures the signal received from each terminal.

In the method according to the invention, the base station compares the measurement results made with the measurement results reported by the subscriber terminal for the same period of time and makes a decision on power control on the basis of this comparison. Power control can also be affected by other quality parameters such as bit error rate.

The aim of the comparison of the measurement results performed by the base station is to remove the effect of fast fading from the measurement-35 results in order to compensate the effect of slow fading with power control. The comparison can advantageously be carried out by calculating the average of the measurement results of the base station and the terminal at the base station. Since the fast fading is independent in different transmission directions (from the base station to the terminal and from the terminal to the base station) and thus of different magnitudes, but the slow fading is of the same magnitude, the average fading effect is reduced and the slow fading effect is emphasized. Thus, the desired power control-10 is achieved without long averaging times.

Figure 3 illustrates a base station receiver of a cellular radio system in which the method according to the invention can be applied. The receiver comprises an antenna 30 with which the received signals are applied to radio frequency lines 31, where the received signal is converted to an intermediate frequency. The signal is passed to converter means 32, where the analog signal is converted to digital form. The receiver further comprises detector means 33 in which the received signal is detected, and 20 means from which the signal 33 is passed on to other parts of the receiver. The receiver also comprises control means 34 for controlling the above-mentioned blocks and performing calculations. The receiver further comprises means 31, 34 for measuring the power of the signal received from the terminal, means 34 for comparing the measurement result of the base station with the measurement result transmitted by the terminal along with the other signal, and means 34 for calculating the power control command to be transmitted to the terminal. . Correspondingly, the transmission power used by the base station's own transmitter can also be calculated in them 34. The base station receiver also has other components, such as filters and amplifiers, but they are not essential to the invention. The receiver described above is a receiver of a digital cellular radio system, but the invention can be applied to an analog system as well.

Figure 4 illustrates a terminal of a cellular radio system in which the method according to the invention can be applied. The terminal comprises means 40 5 for encoding the transmitting signal, means 41 for interleaving the encoded signal, means 42 for transmitting a burst, modulation means 43, the means output signal of which is applied via a transmitter unit 44 and a duplex filter 45 to the antenna 46. The terminal further comprises 10 receiver units 47 to an intermediate frequency, and converter means 48 for converting the signal to digital form, means 49 for detecting the converted signal, deinterleaving means 50, and means 51 for decoding the received signal, the means performing both channel and speech decoding. The terminal further comprises control and calculation means 52 which control the operation of the other blocks mentioned above. The terminal of the cellular radio system according to the invention also comprises means 47, 52 20 for measuring the strength of the signal received from the base station, and means 40-44, 52 for transmitting information about the measurement result to the base station. The terminal also comprises other components, such as filters, but they are not essential to the invention. The terminal described above is a terminal of a digital cellular radio system, but the invention can be applied correspondingly in an analog system as well.

Although the invention has been described above with reference to the example according to the accompanying drawings, it is clear that the invention is not limited thereto, but can be modified in many ways within the scope of the inventive idea set forth in the appended claims.

Claims (5)

A method of controlling transmission power in a cellular radio system comprising in each cell at least one base station (20) communicating with subscriber terminals (21-22) existing in its field, and in which method the base station measures the power level of a friend. the terminals received signal, and the terminal measures the power level of a signal received from the base station and reports the result to the base station, characterized in that the base station compares the measurement results transmitted by the terminal with its own measurement results, and that the base station regulates the transmitting power of the terminal. own transmission effect on the basis of the comparison of the measurement results. 15 2. A method according to claim 1, characterized in that the measurement results of the base station (20) and the terminal (21-22) are measured by averaging the results. 3. A method according to claim 1, characterized in that the base station (20) sends to the terminal (21-22) a power control command using a fast control channel. Cellular radio systems comprising in each cell at least one base station (20) which communicates with subscriber terminals (21-22) in its area, and which base station (20) has means (31, 34) for measuring a signal received from the terminals power level, and the terminals have means (47, 52) for measuring a signal received level from a base station and means (40-44, 52) for reporting the measurement results to the base station, characterized in that the base station has means (34) for comparison. of the measuring results transmitted by the terminal with its own measurement results, and means (34) for controlling the transmission power of the terminal and its own transmission power on the basis of the comparison of the measurement results. > · «M l Hill l.t I <kl I 97926 Cellular radio system according to claim 4, characterized in that the base station has means (34) for performing the comparison between the base station and the terminal's measurement result by averaging the results.