FI80817B - Device for monitoring the condition of the aerial of a base station in a cellular telephone system - Google Patents

Abstract

The invention concerns a device for monitoring the receiving aerial 9 of a base station in a cellular telephone system by determination of the aerial's standing wave ratio, which device comprises a transmission device 2, 7 located at the base station for sending an electrical measurement signal via an aerial lead 11 to the aerial and a measurement device 2 for measuring the measurement signal power reflected from the aerial along the aerial lead 11, 12. In order to reduce the interference caused by the measuring, the device according to the invention is characterized in that the measurement device comprises a field strength indicator in the receiver 2 for one of the speech or measurement channels of the base station, which emits a first narrow-band signal within the transmission frequency band of the transmitter 2, and a frequency transmission device 7 to which the first signal is sent and which creates the abovementioned measurement signal from the first signal by transferring it to the required measurement frequency. <IMAGE>

Description

1 80817 Arrangement for monitoring the condition of an antenna in a cellular telephone base station

The invention relates to an arrangement for monitoring the condition of an antenna of a base station of a cellular telephone system 5 by determining an antenna standing wave ratio, the arrangement comprising transmitter means located at the base station for supplying an electrical measurement signal via the antenna line to the antenna and measuring means for measuring the reflected signal back from the antenna line 10.

In addition to voice channel units, cellular telephone systems use measurement channel units to measure the quality of connections. The purpose of this is e.g. determine which base station is able to establish the best connection with the counter station. A transmitter is not required in the measuring channel, but in order to reduce the number of different units, it is preferable to use a conventional voice pole unit as the measuring channel unit.

20 An essential part of a base station is the receiving and transmitting antennas, the condition of which affects the quality of the connections. The condition monitoring of the antennas can be performed, for example, by measuring their standing wave ratio, i.e. the electrical fit of the antennas to the rest of the receiver and transmitter system.

With the methods currently in use, the measurement is performed by feeding an antenna line to the receiver antenna. through the power and by measuring the reflected power back from the antenna to the antenna line with a broadband power meter-30. Due to the broadband of the power meter, the power used in the measurement must be considerably higher than the maximum expected reception power, so that the measurement does not become interference sensitive, i.e. the signals sent to the base station do not interfere with the measurement. Using high power 35 causes central modulation problems to the receiver. High power interference can be avoided by a duplex filter that separates the measurement signal from the signals to be received. A duplex filter must be installed before the receiver-5 receiver parts, which reduces the sensitivity of the base station because the filter causes losses to the antenna signal.

It is an object of the present invention to provide an arrangement for measuring the condition of an antenna which avoids the above-mentioned problems and which is more advantageous and simpler to implement.

This object is achieved by an arrangement of the type described in the introduction, which according to the invention is characterized in that the measuring means is a field strength indicator of one speech or measuring channel receiver of the base station and that the transmitting means comprises a base station transmitting a first voice or measuring channel transmitter in a narrowband , and a frequency transfer means to which the first signal is input and which generates said measurement signal from the first signal by shifting it to the desired measurement frequency.

The basic idea of the invention is that the standing wave ratio of the receiver antenna is measured using a transmitter and a receiver of the base station's measuring channel. This is an advantage list, because then most of the equipment needed for the measurement already exists at the base station. As stated earlier, a standard voice channel unit is usually used as the measurement channel unit, which usually has an unnecessary transmitter in the measurement channel. This transmitter can now be used to generate a narrowband signal in the transmission frequency band of the base station, which is mixed by the transmission oscillator to the desired measurement frequency. This measurement frequency is precisely the frequency outside the reception frequency band of the base station, so that the measurement signal reflected from the receiver antenna 35 does not cause interference to the other receivers of the base station. The mixed measurement signal is fed to an antenna, from which the reflected power is measured by means of a field strength detector in the receiver of the measurement channel. Since the field strength detector also already exists at the base station for 5 other reasons, only a transmission oscillator needs to be added to the base station for monitoring at least.

Since the transmitter is a conventional voice channel transmitter, the bandwidth of the measurement channel signal is at most the bandwidth of a conventional voice channel signal. Therefore, the measurement takes place frequency-selectively in a very narrow band, so that the power required for the measurement can be kept lower than in the currently known method and no central modulation occurs in the receiver due to the measurement, which causes interference to the speech channels. The duplex filters used in the prior art solutions can thus be omitted.

The measurement signal can be fed to the antenna line through a directional switch that directs all of the measurement signal-20 lite power to the antenna and allows the receiver to receive only signals from the antenna, such as back reflected reflection signal power.

The frequency of the transmission oscillator is preferably 45 MHz, which is the difference between the reception and transmission frequencies in the NMT-900 system. In this case, the control of the receiver and the transmitter does not differ from the control used in the voice channels.

The invention will now be described in more detail by means of an exemplary embodiment with reference to the accompanying drawing, in which Figure 1 shows a block diagram of a base station incorporating a measurement arrangement according to the invention, and Figure 2 is a more detailed representation of blocks 7 and 8 of Figure 1.

Referring now to Figure 1, a base station 35 according to the invention comprises a receiving antenna 9 connected via an antenna line 11, 12 to the antenna input ANT of a distribution amplifier 1. The distribution amplifier has N speech voice channel outputs 1 ... N, each of which is connected to the receiver input 5 RX of the corresponding voice channel unit 31, 32 ... 3II. The transmitter output TX of each voice channel unit 3X --- 3 ,, is connected to the corresponding input 1 ... N of the summing network 6. The output of the summing network 6 is a sum signal comprising all voice channel signals, which is fed to the transmitting antenna 10.

The distribution amplifier 1 further comprises a measuring channel output 0 connected via line 15 to a measuring channel unit 2. This measuring channel unit 2 is substantially similar to the base station voice channel units in a preferred embodiment of the invention. From the measuring channel signal line 15, the measuring signal is fed to the receiver input RX against the measuring channel unit 2. The RFTL output of the transmitter of the measuring channel unit is connected via line 14 to the transmission oscillator 7. The RFTL output is a low-20 level (about -20 dBm) output at the transmitter of the voice channels (and also the measuring channel) used in the speech channels for base station testing purposes. , but the measuring pole is unused. In a preferred embodiment of the invention, it is this output that is used as the output of the measuring channel and the actual transmitter output Tx is terminated in the attenuator 25 RL (artificial load). The output of the transmission oscillator 7 is connected via line 13 to a directional switch 8, which in turn is connected in series to the antenna line between the antenna 9 and the distribution amplifier 1.

The transfer switch 8 and the transfer oscillator 7 are shown in more detail in Fig. 2. The directional switch 8 is a conventional hybrid connection, one branch of which is terminated in a resistor R. A line 13 from the transfer oscillator 7, an antenna-side antenna line 11 and a splitter 1-sided antenna-35 line 12. Direction switch 8 directs the 5,80817 measurement signal from line 13 in its entirety to the branch going to antenna line 11 and prevents the measurement signal from line 13 from entering the branch going to antenna line 12. The signals received by the receiving antenna 9 and the direction switch 8 of the portion of the measurement signal reflected back from the antenna 5 are directed from the antenna line 11 to the antenna line 12. Naturally, another type of directing member can be used instead of the direction switch 8.

The transfer oscillator 7 includes a mixer 73, the second input of which is connected to a line 14 from the RFTL output of the measuring channel transmitter and to the second input of which a crystal oscillator 71 is connected via a buffer amplifier 72. The output of the mixer 73 is connected to line 13. 14 to a frequency of the incoming sig-15 that is above or below the frequency of the signal from line 14 by the frequency of the crystal oscillator 71. In the preferred embodiment of the invention, the frequency of the crystal oscillator 71 is 45 MHz, whereby the transmission oscillator 7 transmits the output signal of the transmitter 20 of the measuring channel unit 2 at the transmission frequency of the measuring channel 0 to a frequency of 45 MHz, which is the reception frequency of the measuring channel 0.

The measuring arrangement according to the invention operates as follows.

The transmitter of the measuring channel supplies to the transmission oscillator 7 a signal at the transmission frequency of the measuring channel 0, which the transmission oscillator transmits to the desired measuring frequency and feeds the measurement signal thus obtained via the directional switch 8 to the receiving antenna 9. via an antenna line to a distribution amplifier 1, from the output 0 of which it is fed to the receiver input RX of the measuring channel unit 2. The reflected power is measured by the ken-35 force detector of the measuring channel unit 2, the result of which is compared with the power of the measurement signal transmitted by 6,80817 to determine the standing wave ratio of the receiving antenna 9. The base station and the so-called telephone system use the information thus obtained about the condition of the receiving antenna in a conventional manner. However, this does not fall within the scope of the actual invention and will therefore not be described in more detail.

The figures and the related description are intended to illustrate the invention. The details of the arrangement according to the invention may vary within the scope of the appended claims. For example, the input signal of the transmission oscillator 7 can be taken from the actual transmitter output TX of the measurement channel after said attenuator.

Claims (6)

An apparatus for checking the condition of the base station's receiving antenna (9) in a cellular telephone system 5 by determining the antenna's standing road relationship, which apparatus comprises a terminal means (2, 7) placed on the base station for delivering an electrical measurement signal via an antenna memory (11). ) to the antenna, and a measuring means (2) for measuring the measured signal power reflected from the antenna 10 along the antenna (11, 12), characterized in that the measuring means consists of the solid state indicator in the receiver (2) of one of the base station's measuring channels, and that the transmitting means comprises the transmitter (2) of the above-mentioned tai or measuring channel of the station, which emits a first narrow band signal, located within the transmitter frequency band, of a frequency switching means (7) to which the first signal is emitted and which of the first signal 20 form each other measurement signal by converting it to the desired measuring frequency. Device according to claim 1, characterized in that the output of the transmitter means (2, 7) is coupled to the antenna line (11, 12) with a directional switching means (8), which directs the measurement signal provided by the transmitter means (2, 7). to the antenna (9) and the power reflected from the antenna (9) to the receiver (2). Device according to claim 1 or 2, characterized in that the frequency converter means 30 is a non-converting oscillator (7). Device according to claim 1, 2 or 3, characterized in that the frequency of the measuring signal is the receiver frequency of the receiver of the above-mentioned tai or measuring channel. 5. Device according to claim 4, characterized in that the frequency of the conversion oscillator (7) or 8081 7 is 45 MHz. Device according to claim 1, 2 or 3, characterized in that the frequency of the measuring signal is outside the receiving frequency path of the base station.