CN101068434A - Measuring device and method for adjacent channel leakage ratio - Google Patents
Measuring device and method for adjacent channel leakage ratio Download PDFInfo
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Abstract
A setting used for measuring leakage ratio of adjacent channel consists of channel configuration module for setting maximum and minimum rated emission power, leakage ratio measurement module for confirming adjacent channel leakage ratio of the first and the second channels being set in adjacent way and for confirming power-increase step length and power backspace value, leakage ratio detection module for detecting whether adjacent channel leakage ratio is in normal range or not and for applying relevant measures accordingly.
Description
Technical field
The present invention relates to the communications field, relate in particular to a kind of adjacent channel leakage than measurement mechanism and method.
Background technology
WCDMA (Wideband CDMA, wideband CDMA), be the shortcut of GSM technology to the 3G smooth evolution, it can support the message transmission rate that 384Kbps does not wait to 2Mbps, state in high-speed mobile, the transmission rate of 384Kbps can be provided, under low speed or indoor environment, then can provide transmission rate up to 2Mbps.Modulation coding method new among the HSDPA will greatly improve user data rate and throughput, also just mean to have strengthened spectrum efficiency.Simultaneously, the user can obtain connection speed faster.Therefore, the HSDPA technology can rise to 14.4Mbit/s (peak rate) from 384kbit/s with the WCDMA downstream rate, and power system capacity increases 2-3 doubly, and time delay reduces greatly.Corresponding with HSDPA, HSUPA provides the data access service of 5.8Mbps in theory by using technology such as Node B scheduling more flexibly, the automatic re-transmission of mixing for the user.
ACLR (Adjacent Channel Leakage Ratio, adjacent channel leakage ratio) is used for weighing regulation to use beyond the transmission channel index of transmission RF energy.Usually because the non-linear system that causes of linear power amplifier produces higher ACLR, adjacent-channel power leaks to be contributed to some extent to the channel background noise.It directly reduces system redundancy amount/capacity, and the ACLR characteristic will influence the operating state and the communications status of other websites greatly.Too high value will be brought so-called near-far interference to the cellphone subscriber.
HSUPA introduces new physical channel E-DPCCH and E-DPDCH, the new physical channel of introducing can cause power peak-to-average force ratio (PAPR) and CM (Cubic Metric) to increase, and therefore radio-frequency (RF) index such as the ACLR test to linear power amplifier is more strict in HSUPA.
HSUPA studies method of measurement and the parameter setting of ACLR.The objective of the invention is in response to this requirement, simultaneously parameter defines irrational shortcoming in some channel configurations in order to overcome in the prior art when ACLR value among the HSUPA measured, and solves the problem that existence is measured in the prior art ACLR value can not reflect modulating performance accurately.
Summary of the invention
At above problem, the invention provides a kind of adjacent channel leakage that is used for portable terminal than measurement mechanism and system, can measure the ACLR value of portable terminal exactly.
Adjacent channel leakage of the present invention comprises than measurement mechanism: the channel configuration module is used to the maximum rated transmitting power and the minimum specified transmitting power of carrying out channel configuration and portable terminal being set; Measurement module is compared in leakage, be connected to the channel configuration module, be used for determining the adjacent channel leakage ratio of first side channel and second side channel by the power of measuring main channel, first side channel and second side channel, and according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage determine flash-up step-length and back-off value than by adaptive approach; And detection module is compared in leakage, be used to detect adjacent channel leakage that leakage measures than measurement module than whether in normal range (NR), adjacent channel leakage than the situation in normal range (NR) under, then increase the laggard pacing amount adjacent channel leakage ratio of maximum rated transmitting power and/or minimum specified transmitting power; , than under the situation in normal range (NR) not maximum rated transmitting power and/or minimum specified transmitting power are reduced to measure the adjacent channel leakage ratio after one or more back-off values at adjacent channel leakage.
Above-mentioned leakage comprises than measurement module: leak than measuring unit, be used for determining by the power of measuring main channel, first side channel and second side channel adjacent channel leakage ratio of first side channel and second side channel; And increase step-length and rollback value determining unit, be used for according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
Above-mentioned leakage comprises than detection module: maximum rated power is leaked and is compared detecting unit, be used for being under the situation of maximum rated transmitting power at portable terminal, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then utilize adaptive approach to be increased to maximum rated power by one or more flash-up step-lengths, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off, further measure the adjacent channel leakage ratio by deduct one or more power back-offs from maximum rated power; And minimum specified Power leakage compares detecting unit, be used for being under the situation of minimum specified transmitting power at portable terminal, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to minimum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off, further measure the adjacent channel leakage ratio by deduct one or more back-off step-lengths from minimum rated power.
At the adjacent channel leakage that utilizes one or more power step sizes to carry out to test behind the back-off than in normal range (NR), judge that corresponding maximum rated transmitting power and/or minimum specified transmitting power are whether in prescribed limit, if in prescribed limit, then the adjacent channel leakage of Ce Lianging compares compliant, if not in prescribed limit, then the adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
Above-mentioned adjacent channel leakage is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal than measurement mechanism.
Adjacent channel leakage ratio measuring method of the present invention may further comprise the steps: step S202, measurement mechanism carry out channel configuration and the maximum rated transmitting power and the minimum specified transmitting power of portable terminal are set; Step S204, measurement mechanism is determined the adjacent channel leakage ratio of first side channel and second side channel by the power of measuring main channel, first side channel and second side channel, and according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage determine flash-up step-length and back-off value than by adaptive approach; And step S206, measurement mechanism detect adjacent channel leakage than whether in normal range (NR), adjacent channel leakage than the situation in normal range (NR) under, then increase the laggard pacing amount adjacent channel leakage ratio of maximum rated transmitting power and/or minimum specified transmitting power; , than under the situation in normal range (NR) not maximum rated transmitting power and/or minimum specified transmitting power are reduced to measure the adjacent channel leakage ratio after one or more back-off values at adjacent channel leakage.
Above-mentioned step S204 comprises: the adjacent channel leakage ratio of determining first side channel and second side channel by the power of measuring main channel, first side channel and second side channel; And according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
Above-mentioned step S206 comprises: be at portable terminal under the situation of maximum rated transmitting power, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then will utilize one or more flash-up step-lengths to be increased to maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off, further measure the adjacent channel leakage ratio by utilize one or more power to reduce step-length from maximum rated power; And be at portable terminal under the situation of maximum rated transmitting power, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off by deduct one or more back-off step-lengths from maximum rated power, further measure the adjacent channel leakage ratio.
Carry out the adjacent channel leakage tested behind the back-off than in normal range (NR) deducting one or more back-off step-lengths, judge that corresponding maximum rated transmitting power and/or minimum specified transmitting power are whether in prescribed limit, if in prescribed limit, then the adjacent channel leakage of Ce Lianging compares compliant, if not in prescribed limit, then the adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
Above-mentioned adjacent channel leakage ratio measuring method is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal.
By the present invention, can measure the ACLR value of portable terminal exactly, the modulating characteristic of reflect mobile terminal.
Description of drawings
Accompanying drawing described herein is used to provide further understanding of the present invention, constitutes the application's a part, and illustrative examples of the present invention and explanation thereof are used to explain the present invention, do not constitute improper qualification of the present invention.In the accompanying drawings:
Figure 1A and Figure 1B are the block diagram of adjacent channel leakage according to the present invention than measurement mechanism;
Fig. 2 is the flow chart according to adjacent channel leakage ratio measuring method of the present invention; And
Fig. 3 is the flow chart of adjacent channel leakage ratio measuring method according to an embodiment of the invention.
Embodiment
Below with reference to accompanying drawing, describe the specific embodiment of the present invention in detail.
The present invention relates to mobile communication system, relate in particular to mobile communication system WCDMAHSUPA terminal ACLR conformance test method.
The present invention proposes a kind of under the collocation method of new channel the method for measurement of ACLR, this method is according to the different configurations of E-DCH channel with the DCH channel, comprise different numbers of channel and different-energy, show ACLR (Adjacent Channel Leakage Ratio) performance characteristics, for WCDMA HSUPA terminal consistency test provides solution.
Figure 1A and Figure 1B are the block diagram of adjacent channel leakage according to the present invention than measurement mechanism.Shown in Figure 1A, adjacent channel leakage of the present invention comprises than measurement mechanism: channel configuration module 102 is used to the maximum rated transmitting power and the minimum specified transmitting power of carrying out channel configuration and portable terminal being set; Leakage is than measurement module 104, be connected to described channel configuration module, be used for determining the adjacent channel leakage ratio of first side channel and second side channel by the power of measuring main channel, first side channel and second side channel, and according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage determine flash-up step-length and back-off value than by adaptive approach; And leak than detection module 106, be used to detect adjacent channel leakage that described leakage measures than measurement module than whether in normal range (NR), adjacent channel leakage than the situation in normal range (NR) under, then increase the laggard pacing amount adjacent channel leakage ratio of maximum rated transmitting power and/or minimum specified transmitting power; , than under the situation in normal range (NR) not maximum rated transmitting power and/or minimum specified transmitting power are reduced to measure the adjacent channel leakage ratio after one or more back-off values at adjacent channel leakage.
Shown in Figure 1B, above-mentioned leakage comprises than measurement module 104: leak than measuring unit 104-2, be used for determining by the power of measuring main channel, first side channel and second side channel adjacent channel leakage ratio of first side channel and second side channel; And increase step-length and rollback value determining unit 104-4, be used for according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
Above-mentioned leakage comprises than detection module 106: maximum rated power is leaked than detecting unit 106-2, be used for being under the situation of maximum rated transmitting power at portable terminal, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off, further measure the adjacent channel leakage ratio by deduct one or more back-off step-lengths from maximum rated power; And minimum specified Power leakage is than detecting unit 106-4, be used for being under the situation of minimum specified transmitting power at portable terminal, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to minimum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off, further measure the adjacent channel leakage ratio by deduct one or more back-off step-lengths from minimum rated power.
Carry out the adjacent channel leakage tested behind the back-off than in normal range (NR) deducting one or more back-off step-lengths, judge that corresponding maximum rated transmitting power and/or minimum specified transmitting power are whether in prescribed limit, if in prescribed limit, then the adjacent channel leakage of Ce Lianging compares compliant, if not in prescribed limit, then the adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
Above-mentioned adjacent channel leakage is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal than measurement mechanism.
Fig. 2 is the flow chart according to adjacent channel leakage ratio measuring method of the present invention.As shown in Figure 2, adjacent channel leakage ratio measuring method of the present invention may further comprise the steps:
Step S202, measurement mechanism carry out channel configuration and the maximum rated transmitting power and the minimum specified transmitting power of portable terminal are set, and dispose corresponding β
c, β
d, β
Ec, β
EcAnd β
HsThe value of (power control ratio);
Step S204, measurement mechanism is determined the adjacent channel leakage ratio of first side channel and second side channel by the power of measuring main channel, first side channel and second side channel, and according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
Test is faced channel and second through the main channel, first behind the RRC filter filtering and is faced the power of channel and ratio each other, can obtain corresponding ACLR value.According to transmitting power and last time the ACLR test result, utilize adaptive algorithm to determine the flash-up step-length, determine back-off value 0.5dBm-3dBm.
Step S206, measurement mechanism detect adjacent channel leakage than whether in normal range (NR), adjacent channel leakage than the situation in normal range (NR) under, then increase the laggard pacing amount adjacent channel leakage ratio of maximum rated transmitting power and/or minimum specified transmitting power; , than under the situation in normal range (NR) not maximum rated transmitting power and/or minimum specified transmitting power are reduced to measure the adjacent channel leakage ratio after one or more back-off values at adjacent channel leakage.
Judge to measure whether conformance with standard of ACLR value.Carry out power terminal transmitting power rollback if the ACLR value in critical field, then adopts self adaptation to increase step-length, measure the ACLR value; If the standard of not meeting, then power reduces to measure ACLR after the rollback value again, if this moment power reduction to standard code maximum transmission power lower limit, ACLR does not still meet standard, then this test is not passed through; If normal, continue to carry out previous step, reduce transmitting power until standard code maximum transmission power lower limit by the variable power step-length, measure ACLR value lower limit.In this process, any non-compliant transmitting power of ACLR value represents that all this test can not pass through.
Step S204 comprises: the adjacent channel leakage ratio of determining first side channel and second side channel by the power of measuring main channel, first side channel and second side channel; And according to maximum rated transmitting power and/or minimum specified transmitting power and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
Step S206 comprises: be at portable terminal under the situation of maximum rated transmitting power, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off by deduct one or more back-off step-lengths from maximum rated power, further measure the adjacent channel leakage ratio; And be at portable terminal under the situation of minimum specified transmitting power, detect adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to minimum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then carry out back-off by deduct one or more back-off step-lengths from minimum rated power, further measure the adjacent channel leakage ratio.
Carry out the adjacent channel leakage tested behind the back-off than in normal range (NR) deducting one or more back-off step-lengths, judge that corresponding maximum rated transmitting power and/or minimum specified transmitting power are whether in prescribed limit, if in prescribed limit, then the adjacent channel leakage of Ce Lianging compares compliant, if not in prescribed limit, then the adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
Above-mentioned adjacent channel leakage ratio measuring method is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal.
Fig. 3 is the flow chart of adjacent channel leakage ratio measuring method according to an embodiment of the invention.The following (see figure 3) of ACLR method of measurement key step of the present invention:
At first carry out channel configuration and channel energy and distribute (S302-S304), with 1 DPCCH, m DPDCH channel, 1 HS-DPCCH channel and 1 E-DPCCH and k E-DPDCH channel group are synthesized a compound channel, and dispose corresponding β
c, β
d, β
Ec, β
EcAnd β
HsValue, be provided with end in standard code maximum transmission power thresholding as 24dBm (S306).Terminal transmits through after RRC filter (roll-off factor α=0.22) filtering (S308), the power of test main channel, first Lin Dao and second Lin Dao, calculate first and face channel and second and face channel and main channel ratio each other, can obtain first and face the ACLR value (S310) that channel and second faces channel.If the ACLR value is in normal range (NR), promptly first faces channel ACLR<33.2dB and second and faces channel ACLR<43.2dB, carries out next step (S312).
According to transmitting power and last time the ACLR test result, utilize adaptive algorithm to determine the flash-up step-length, as when transmitting power greater than 18dBm during less than 20dBm, it is 2dB that step-length is set, when power during greater than 20dBm, step-length is set to 0.5dB, determines transmitting power (S314-S316).
If the ACLR value in normal range (NR), continues to carry out S310 and S312 step, otherwise judges whether maximum transmission power is higher than the standard maximum transmission power upper limit (as 25dBm) (S318), if test is passed through.
If the ACLR value is in normal range (NR), measure ACLR after utilizing rollback value of adaptive algorithm power reduction, as when transmitting power greater than 18dBm during less than 20dBm, it is 2dB that step-length is set, when power during greater than 20dBm, step-length is set to 0.5dB, and maximum power rollback scope is selected (S320-S322) between definite back-off value 0.5dBm-3dBm.
If whether the ACLR value is lower than standard code transmitting power lower limit such as 18.3dBm after in normal range (NR), judging rollback, if not, test is passed through.If then test is not by (S324).
If test is passed through, and determine last back-off value; Otherwise represent that this test can not pass through.Final transmitting power is to be between the bound of standard code maximum power, at this moment ACLR conformance with standard standard.
The present invention is according to the channel configuration difference, and its maximum transmission power is different, and maximum transmission power allows for example changing in the 18.3dBm-25.7dBm scope, has certain flexibility.
The present invention according to transmitting power and last time the ACLR test result utilize adaptive algorithm to determine the rollback step-length of measured power, when transmitting power is big, the back-off step-length is big as 1dB, in transmitting power hour, the back-off step-length is less as 0.5dB, has avoided measuring inaccurate phenomenon because of adopting even test step-length ACLR when transmitting power is big to change too fast causing.
The present invention adopts for example 0.5dB-3dB of back-off, can reduce the influence that amplifier nonlinearity worsens the ACLR value, and the ACLR value of surveying more can accurately reflect the radio-frequency head modulating characteristic.
The present invention has reduced power peak-to-average force ratio PAPR (Peak-to AveragePower Ratio) and CM (Cubic Metric) value to a certain extent.
The above is the preferred embodiments of the present invention only, is not limited to the present invention, and for a person skilled in the art, the present invention can have various changes and variation.Within the spirit and principles in the present invention all, any modification of being done, be equal to replacement, improvement etc., all should be included within protection scope of the present invention.
Claims (10)
1. an adjacent channel leakage that is used for portable terminal is characterized in that comprising than measurement mechanism:
The channel configuration module is used to the maximum rated transmitting power and the minimum specified transmitting power of carrying out channel configuration and described portable terminal being set;
Measurement module is compared in leakage, be connected to described channel configuration module, be used for determining the adjacent channel leakage ratio of described first side channel and described second side channel by the power of measuring main channel, first side channel and second side channel, and according to described maximum rated transmitting power and/or the specified transmitting power of described minimum and last time adjacent channel leakage determine flash-up step-length and back-off value than by adaptive approach; And
Detection module is compared in leakage, be used to detect described adjacent channel leakage that described leakage measures than measurement module than whether in normal range (NR), described adjacent channel leakage than the situation in normal range (NR) under, then increase the described adjacent channel leakage ratio of the laggard pacing amount of described maximum rated transmitting power and/or the specified transmitting power of described minimum; At described adjacent channel leakage than under the situation in normal range (NR) not, will described maximum rated transmitting power and/or the specified transmitting power of described minimum reduce the described adjacent channel leakage ratio of measurement after one or more back-off values.
2. adjacent channel leakage according to claim 1 is characterized in that than measurement mechanism described leakage comprises than measurement module:
Leakage is used for determining by the power of measuring main channel, first side channel and second side channel adjacent channel leakage ratio of described first side channel and described second side channel than measuring unit; And
Increase step-length and rollback value determining unit, be used for according to described maximum rated transmitting power and/or the specified transmitting power of described minimum and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
3. adjacent channel leakage according to claim 1 is characterized in that than measurement mechanism described leakage comprises than detection module:
Maximum rated power is leaked and is compared detecting unit, be used for being under the situation of maximum rated transmitting power at described portable terminal, detect described adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to described maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then, further measure the adjacent channel leakage ratio by deduct one or more back-off values from described maximum rated power; And
Minimum specified Power leakage compares detecting unit, be used for being under the situation of minimum specified transmitting power at described portable terminal, detect described adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to described minimum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then, further measure the adjacent channel leakage ratio by deducting one or more back-off values from described minimum rated power.
4. adjacent channel leakage according to claim 1 compares measurement mechanism, it is characterized in that, deducting the adjacent channel leakage tested after one or more back-off values than in normal range (NR), judge that corresponding maximum rated transmitting power and/or the specified transmitting power of described minimum are whether in prescribed limit, if in described prescribed limit, then the described adjacent channel leakage of Ce Lianging compares compliant, if not in described prescribed limit, then the described adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
5. it is characterized in that than measurement mechanism according to each described adjacent channel leakage in the claim 1 to 4 that described adjacent channel leakage is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal than measurement mechanism.
6. an adjacent channel leakage ratio measuring method that is used for portable terminal is characterized in that, said method comprising the steps of:
Step S202, measurement mechanism carry out channel configuration and the maximum rated transmitting power and the minimum specified transmitting power of described portable terminal are set;
Step S204, described measurement mechanism is determined the adjacent channel leakage ratio of described first side channel and described second side channel by the power of measuring main channel, first side channel and second side channel, and according to described maximum rated transmitting power and/or the specified transmitting power of described minimum and last time adjacent channel leakage determine flash-up step-length and back-off value than by adaptive approach; And
Step S206, described measurement mechanism detect described adjacent channel leakage than whether in normal range (NR), described adjacent channel leakage than the situation in normal range (NR) under, then increase the described adjacent channel leakage ratio of the laggard pacing amount of described maximum rated transmitting power and/or the specified transmitting power of described minimum; At described adjacent channel leakage than under the situation in normal range (NR) not, will described maximum rated transmitting power and/or the specified transmitting power of described minimum reduce the described adjacent channel leakage ratio of measurement after one or more back-off values.
7. adjacent channel leakage ratio measuring method according to claim 6 is characterized in that, described step S204 comprises:
Determine the adjacent channel leakage ratio of described first side channel and described second side channel by the power of measuring main channel, first side channel and second side channel; And
According to described maximum rated transmitting power and/or the specified transmitting power of described minimum and last time adjacent channel leakage than determining flash-up step-length and back-off value by adaptive approach.
8. adjacent channel leakage ratio measuring method according to claim 6 is characterized in that, described step S206 comprises:
Be at described portable terminal under the situation of maximum rated transmitting power, detect described adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to described maximum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then, further measure the adjacent channel leakage ratio by deduct one or more back-off values from described maximum rated power; And
Be at described portable terminal under the situation of minimum specified transmitting power, detect described adjacent channel leakage than whether in normal range (NR), if in normal range (NR), then one or more flash-up step-lengths are increased to described minimum rated power by adaptive approach, further measure the adjacent channel leakage ratio, if not in normal range (NR), then, further measure the adjacent channel leakage ratio by deducting one or more back-off values from described minimum rated power.
9. adjacent channel leakage ratio measuring method according to claim 6, it is characterized in that, deducting the adjacent channel leakage tested after one or more back-off values than in normal range (NR), judge that corresponding maximum rated transmitting power and/or the specified transmitting power of described minimum are whether in prescribed limit, if in described prescribed limit, then the described adjacent channel leakage of Ce Lianging compares compliant, if not in described prescribed limit, then the described adjacent channel leakage ratio of Ce Lianging does not meet standard, and test is not passed through.
10. according to each described adjacent channel leakage ratio measuring method in the claim 6 to 9, it is characterized in that described adjacent channel leakage ratio measuring method is used to measure the adjacent channel leakage ratio of HSUPA WCDMA terminal.
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| CN104579521B (en) * | 2014-12-25 | 2017-04-26 | 中国科学院信息工程研究所 | Spectral centroid based automatic detection method and system for video leakage signal |
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| US10904840B2 (en) | 2017-06-20 | 2021-01-26 | SZ DJI Technology Co., Ltd. | Method and device for setting transmission power of communication system |
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| CN109302207B (en) * | 2018-11-30 | 2020-01-07 | 维沃移动通信有限公司 | Parameter setting method and mobile terminal |
| CN110430001A (en) * | 2019-08-30 | 2019-11-08 | 联想(北京)有限公司 | A kind of carrier wave optimization method and system |
| CN111490833A (en) * | 2020-04-23 | 2020-08-04 | 北京字节跳动网络技术有限公司 | Method, device, system and medium for adjusting transmitting signal of antenna |
| CN111490833B (en) * | 2020-04-23 | 2022-07-22 | 北京字节跳动网络技术有限公司 | Method, device, system and medium for adjusting transmitting signal of antenna |
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