Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
  • H04W52/04—TPC
  • H04W52/18—TPC being performed according to specific parameters
  • H04W52/24—TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters

Definitions

• radio base stations are provided, to which wireless network termination devices are connected.
• a network termination device represents the termination of a communication network - for example a public or private communication network - and provides an interface - for example an analog or digital telephone or an ISDN interface - to which communication terminals - for example analog or digital telephone devices or ISDN Communication terminals - can be connected.
• the information to be transmitted from or to the communication terminals is transmitted over the radio link between the network termination devices and the radio base stations by radio signals formed in accordance with the standardized DECT transmission method or the CDMA transmission method.
• a high-frequency signal to be transmitted is formed in a radio base station, for example in accordance with the CDMA transmission method.
• the transmission signal with a lower level or with a lower power is transmitted via a line to an antenna transceiver unit which contains a line amplifier and which is connected to an antenna emitting the high-frequency transmission signal as a radio signal.
• the antenna transmitter / receiver unit is usually attached to the top of an antenna mast near the antenna.
• a radio signal is received in the network termination device and the transmitted information is derived from the received high-frequency received signal.
• the antenna transmit
• Receiver unit also contains a low-noise amplifier for a receive signal that is sent directly from the antenna - with separate transmitter / receiver unit and antenna transmitter / receiver unit - or via a transmitter / receiver switch - with common transmitter / receiver antenna - to the amplifier.
• the power of the transmitted radio signal or the level of the high-frequency transmission signal is not only determined by the transmission method used - for example in the CDMA transmission method - level change but also by the antenna transmitter / receiver units and by the RF cable leading to the radio base station or significantly influenced the line.
• the level of the high-frequency transmission signal will have a wide variety of level values.
• the antenna transmitter / receiver unit in particular will amplify the high-frequency transmit signal considerably differently under a wide variety of temperature conditions - for example direct sunlight during the day and low night temperatures - and thus additionally influence the level of the radio signal.
• the level of the received signal at the radio base station is influenced.
• the level of the high-frequency transmission signal represents an essential function by means of which optimum reception conditions are achieved with the network termination devices and minimal interference with the other network termination devices. Since high fluctuations in the level of the received radio signal, particularly in radio networks implemented according to the CDMA transmission method, can lead to different reception powers at the network termination devices or to disturbed operation, the radio signal received there or the high-frequency transmission signal in the radio base station should be as intended as possible Have levels.
• the object underlying the invention is to be seen in designing a radio base station or the transmission path in a radio base station in such a way that a radio signal with approximately the intended level is emitted by the antenna, whereby level changes caused by the transmission method are to be ensured.
• the object is achieved by the features of patent claim 1.
• the essential aspect of the method according to the invention is to be seen in the fact that the level of the transmitted signal received is measured in the transmitting / receiving unit and the level of the transmitted signal transmitted over the line is measured in the antenna transmitting / receiving unit.
• the level difference of the measured levels is then determined and compared with a predetermined level difference and the level of the transmission signal is influenced in such a way that the determined level difference is kept approximately at the predetermined level difference.
• the total gain of the arrangement formed by the transmitting / receiving unit, the line and the antenna transmitting / receiving unit is set to a predetermined value or amplification factor, and this setting is checked and, if necessary, adjusted.
• the comparison of the level differences and the influencing of the transmission signal (fs) can be carried out in the transmission / reception unit (SE) or alternatively in the antenna transmission / reception unit (ASE), the measured levels being transmitted to the transmission / reception unit (SE ) or the antenna transmission / reception unit (ASE) are transmitted - claim 2.
• a major advantage of the method according to the invention is that the level of the transmission signal on the antenna is kept approximately at a value dependent on the transmission method, independently of what length and which transmission properties - in particular attenuation - the line between the transceiver units has, the different transmission properties being caused in particular by different cable types and by environmental influences such as strong temperature fluctuations.
• the inventive regulation of the level of the transmission signal allows optimal Reception conditions in the network termination facilities are guaranteed.
• Level of the transmission signal transmitted via the line is measured before and after amplification of the radio signal and the additional measurement result is transmitted to the transmission / measurement unit via the line.
• the additionally measured level is transmitted to the transmitting / receiving unit via the line and a further level difference of the measured levels is determined. In the event of a deviation of the further level difference, this is included in the influencing of the transmission signal (fs) - claim 3.
• This measure additionally enables the different amplification factors of the antenna transmitter / receiver unit, caused by strong temperature fluctuations, to be detected and thereby compensated that the measurement result is included in the regulation of the level of the transmission signal.
• the measurements of the level of the transmission signal are advantageously carried out continuously or at regular time intervals.
• a constant measurement of the level allows a detailed regulation of the level, whereas a measurement at time intervals means a lower dynamic load on a microprocessor implementing the method according to the invention.
• integration of the measured values by means of which hectic regulation is smoothed can also be dispensed with.
• the measured level values of the level of the transmission signal are advantageously integrated - claim 5.
• a transmission signal is coupled into the transmitting / receiving unit with the aid of a switch connected to the line and a received signal received with the aid of the antenna is coupled out, the transmission signal being fed to the switch via a controllable attenuator and an amplifier .
• the transmission signal is coupled out and the reception signal is coupled in with the aid of a switch connected to the line, the transmission signal being routed via an antenna transmission amplifier and the received radio signal via an antenna reception amplifier.
• the transmit signal is coupled in and the receive signal is coupled out with the help of a further switch connected to the antenna line, and each with the aid of power meters arranged in the antenna transmitter / receiver unit and the transmitter / receiver unit
• the level of the transmission signal is measured and a setting signal for setting the attenuator is calculated in the transmitter / receiver unit with the aid of a microprocessor .
• the level of the transmission signal is measured in the antenna transmitter / receiver unit and in the transmitter / receiver unit, the level difference is determined and the level difference is set with the aid of the attenuator in such a way that a transmission method-related level in the antenna transmitter - / receiving unit is measured.
• This set level difference is kept approximately constant in constant operation with the aid of the attenuator.
• the variable attenuator can be set to a basic setting by the measured level difference between the two transmitting / receiving units, and during operation, the level difference of the transmitted signal becomes before and after the gain m of the antenna transmitter / receiver unit is measured and the attenuator is set according to the level difference.
• the transmission properties of the line change less than that of the temperature-dependent antenna transmitter amplifier, ie considerably higher level fluctuations are caused by the antenna transmitter amplifier.
• the level difference caused by the line should be determined at larger intervals and the variable attenuator set according to the level difference deviations determined.
• Fig. 1 m a block diagram of an arrangement for realizing the inventive method
• the 1 shows a radio base station BS which is connected via a line L to an antenna transceiver unit ASE.
• the line L can be implemented using a wide variety of coaxial line types with a wide variety of damping coatings.
• the antenna transmitter / receiver unit ASE is connected directly to an antenna A, whereby the antenna transmitter / receiver unit ASE and the antenna A can be arranged in a housing or separately.
• further connections are provided, for example, for energy supply and for information exchange between the transmitting / receiving unit SE and the antenna transmitting / receiving unit ASE.
• the line L is routed to a transmitting / receiving unit SE, in which the line L is connected to a first switch W1.
• a radio-frequency transmission signal fs intended for radio transmission is formed in the radio base station BS and is transmitted to a first variable attenuator DG1 arranged in the transmission / reception unit SE, for example by a controllable one Pin diode implemented first attenuator DG1 is further with a first
• Amplifier VI connected in which the high-frequency transmission signal fs is amplified.
• the high-frequency transmission signal fs is then coupled into line L with the aid of the first switch W1.
• the high-frequency transmission signal fs transmitted via the line L is decoupled in the antenna transmission / reception unit ASE with the aid of a second switch W2 and passed to an antenna transmission amplifier AV.
• this antenna transmit amplifier AV - also referred to in the professional world as high power amplifier HPA - the transmit signal fs is amplified to the required or to the intended transmit power.
• After this amplification of the high-frequency transmission signal fs it is transmitted to antenna A via a third switch W3 or coupled to the connection leading to antenna A.
• the method according to the invention essentially relates to this previously described transmission path.
• radio signals are also received with the aid of the antenna A as reception signals.
• the received signal is decoupled using the third crossover W3 and, after amplification by an antenna receiving amplifier EV - also known in the art as a low noise amplifier LNA - is coupled into the line L using the second crossover W2.
• an antenna receiving amplifier EV - also known in the art as a low noise amplifier LNA - is coupled into the line L using the second crossover W2.
• the received signal transmitted to a second, variable attenuator DG2.
• the received signal is amplified with the aid of a second amplifier V2 in such a way that it can be transmitted to the further processing components - not shown - of the radio base station BS.
• the level of the introduced high-frequency transmission signal fs is measured in the transmitting / receiving unit SE with the aid of a first level measuring device PM1.
• a first sensor SI is provided for decoupling a measurement signal ms, which is arranged, for example, by a line parallel to the line carrying the high-frequency signal.
• the decoupled measurement signal is measured in the first level measuring device PM1 and converted into digital information representing the logarithm of the measured level value pwl and transmitted to a microprocessor MP - indicated in FIG. 1 by an arrow labeled pwl.
• an additional connection V - implemented, for example, by a 2-wire copper line - is led together with the line L to the antenna transmitter / receiver unit ASE and is connected there to a second level measuring device PM2.
• a second sensor S2 arranged in front of the antenna transmitter amplifier AV and a third sensor S3 arranged after the antenna transmitter amplifier AV are connected to this second level measuring device PM2. With the help of these two sensors S2, S3, a measuring signal ms is coupled out and transmitted to the second level measuring device PM2.
• FIG. 2 shows the sequence of a measurement routine MR that is implemented in the microprocessor MP.
• the measurement routine MR is initialized and switched on when the radio base station BS is started up Preset value vw read in and saved. The reading takes place, for example, via a data interface DS, which is connected to a control unit of the radio base station, not shown, the predetermined value vw m being stored in a memory of the control unit or being transmitted to the control unit via an operating technology interface, not shown.
• the predetermined value vw indicates the level difference at which the high-frequency transmission signal ts, which is conducted via the transceiver SE, the line (L) and the antenna transceiver unit ASE, is to be kept.
• the measuring routine MR then forms a first and second level measurement request mwal, mwa2 and transmits them to the first and second level measurement devices PM1, PM2.
• a measured value mw present at the sensors S1..3 is then recorded and information representing the digital level as first to third level measured values pwl..3 is transmitted to the microprocessor MP.
• the value pdwl of a first level difference is formed by forming the difference between the first and second level measurement values pwl, pw2. Furthermore, a value pdw2 of a second level difference is formed by forming the difference between the second and third level measurement values pw2, pw3.
• the value pdw3 of a third level difference is formed by summing these two values pdwl, pdw2.
• the value pdw 3 of this third level difference represents the overall amplification factor of the high-frequency transmission signal fs, which is conducted via the transmission / reception unit SE, the line (L) and the antenna transmission / reception unit ASE.
• the value pdw3 of the third level difference is compared with the predetermined value vw and the deviation is determined.
• This deviation represents the one basic setting information ei ', which transmits to the first and second attenuator DG1.2 becomes.
• This setting information ei in particular sets the damping of the first attenuator DG1 in such a way that the value pdw3 of the third level difference and the predetermined value vw are approximately the same. This means that the total gain factor explained above is approximately equal to the predetermined value.
• This basic setting information ei ' sets the first variable attenuator DG1 to basic attenuation.
• the first attenuator DG1 is set to low attenuation for lines L with high level attenuation and to high attenuation for lines L with low level attenuation.
• the setting information ei can be formed either by the values pdw2, pdw3 of the second or third level difference. If it is formed by the value pdw3 of the third level difference, the setting information ei is formed as in the commissioning. When the setting information ei is formed by the value pdw2 of the second level difference, the deviations of the value pdw2 of the second level difference from the value pdw2 determined during commissioning are determined and this is determined as setting information ei. This setting information ei essentially serves to compensate for the different amplification factors of the antenna transmitter amplifier AV caused by the strong temperature fluctuations.
• the value pdwl of the first level difference is additionally checked (not shown in FIG. 2) at larger time intervals in order to correct, for example, a damping shift of the line L which is also caused by temperature fluctuations.
• a radio communication network - not shown - different predetermined values can be loaded into the microprocessor MP in order to influence a remote-controlled setting of the sizes of radio cells determined by the level of the emitted transmission signal fs.
• radio cells can be configured and, if necessary, changes in position of the radio base station BS can be avoided.
• the level of the radio signal at the edges of the radio cells can be set such that undisturbed operation of the network termination device is ensured.
• the level relationships determined for the transmission path and influenced by different lines L and amplification factors can also be transmitted to the transmission path — not shown in FIG. 2.
• further setting information is formed, by means of which the second damping element DG2 is set.
• the setting information ei, eie for the transmission and reception path are approximately the same, which results in approximately the same setting of the second variable attenuator DG2.

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• Engineering & Computer Science (AREA)
• Computer Networks & Wireless Communication (AREA)
• Signal Processing (AREA)
• Mobile Radio Communication Systems (AREA)

Applications Claiming Priority (3)

Publications (1)

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Family Applications (1)

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• 1998
  • 1998-08-11 DE DE19836375A patent/DE19836375C1/de not_active Expired - Fee Related
• 1999
  • 1999-08-11 US US09/762,735 patent/US6804498B1/en not_active Expired - Fee Related
  • 1999-08-11 WO PCT/DE1999/002512 patent/WO2000010260A2/de not_active Application Discontinuation
  • 1999-08-11 BR BR9912904-3A patent/BR9912904A/pt not_active IP Right Cessation
  • 1999-08-11 EP EP99952364A patent/EP1104596A2/de not_active Withdrawn
  • 1999-08-11 CN CNB998120049A patent/CN1143451C/zh not_active Expired - Fee Related

Non-Patent Citations (1)

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