METHOD FOR CONFIGURING TRANSMISSION POWER FOR A DEMODULATION REFERENCE SIGNAL AND AND EQUIPMENT FOR

专利摘要:
Method for Setting Transmit Power for a Demodulation Reference Signal and Equipment for Setting Transmit Power for a Demodulation Reference Signal The present disclosure shows a method for setting transmit power for a demodulation reference signal (dmrs) , and the method comprises: setting the ratio between the transmit power of a dmrs in each layer of a resource element (re) and the data transmission power in a corresponding layer to be a constant value. meanwhile, the present disclosure discloses an apparatus for configuring transmit power for the dmrs. the present disclosure greatly improves the correct data frame decoding ratio, and improves decoding performance. the present disclosure allows the network side to not need to notify an UE of the corresponding relationship between the transmit power of the dmrs in each layer and the data transmission power in the corresponding layer, which simplifies blocking of control signaling on the network side. . as the corresponding relationship between the dmrs transmit power in each layer and the dmrs transmit power in each layer and the data transmission power in the corresponding layer is configured in the ue, the ue can constitute the channel estimate without waiting for the network-side notification, which improves channel estimation efficiency.
公开号:BR112012019478B1
申请号:R112012019478-0
申请日:2010-10-20
公开日:2021-06-15
发明作者:Yunfeng Sun；Ewnfeng Zhang；Jing Jiang；Junfeng Zhang
申请人:Zte Corporation；
IPC主号:

专利说明:

TECHNICAL FIELD
The present disclosure relates to a design technique for offsetting the Resource Element (RE) power corresponding to the Demodulation Reference Signal (DMRS) relative to the data resource element, in particular a method for setting the power of transmission and equipment for a Demodulation Reference Signal. HISTORIC
Advanced multi-antenna technology is one of the main technologies of the Long Term Evolution Advanced (LTE-A or LTE-Advanced) system and is used to improve the system's transmission speed. To make channel quality measurement and data demodulation after the introduction of advanced multi-antenna technology, the LTE-A system is defined in two types of pilot signals: DMRS and Channel State Information-Reference Signal (CSI-RS) , where the DMRS is used for the Physical Downlink Shared Channel (PDSCH) demodulation reference signal, and the CSI-RS measured Channel State Information (CSI) reference signal is used for the Channel Quality Indicator (CQI) reporting information ), Precoding Matrix Indicator (PMI), Rank Indicator (RI) and the like. The structures of both types of reference signals can be used to support new LTE-A system technology such as Coordinated Multi-Point (CoMP) and spatial multiplexing.
In the LTE system, the pilot frequency is measured adopting the Common Reference Signal(CRS), that is, all users use the public pilot frequency to perform a channel estimation; CRS needs an extra notification message from the transmitting side to notify the receiving side which pre-treatment process is adopted for the transmitted data, and the extra notification message brings the extra blocking. Furthermore, in MU-MIMO, a plurality of CRSs used by the UE are the same, which cannot realize pilot frequency orthogonality. Therefore, interference cannot be estimated.
In the LTE-A system, to reduce pilot frequency blocking, CSI-RS and DMRS are designed separately, where the DMRS and data adopt the same pre-treatment process; meanwhile, the DMRS is particularly mapped according to the classification of channel information available to the programming user. Therefore, the blocking can be self-adaptively adjusted according to the classification information, so that the blocking can be greatly reduced as a relatively smaller class.
Fig. 1 shows a diagram of DMRS supporting a normal subframe and a specific subframe in the Cyclic Prefix (CP) of the LTE_A normal system. As shown in Fig. 1, the DMRS design pattern has already been determined in the current discussion, where only the corresponding sand point grid RE shown in the diagram is used to support the DMRS when the classification number is used in the transmission of downlink is less than or equal to 2, adopting the Orthogonal Coverage Code (OCC) with length 2 to mix two adjacent symbols of Orthogonal Frequency Division Multiplexing (OFDM) in the time domain. Two RE sets are used to support the DMRS when the classification number is greater than or equal to 3 and less than or equal to 4, and the two RE sets are respectively corresponding to the sand point grid and the crosshair line grid in the diagram, where the maximum orthogonal Code Division Multiplexing (CDM) DMRS layer number in each RE set is 2, and the orthogonal coverage code with a length of 2 is adopted to perform orthogonal mixing on the two adjacent OFDM signals in the time domain simultaneously in each set. Although the OCC code with a length of 4 is adopted to perform orthogonal mixing in the time domain, the direction of each set of the two RE sets to support the DMRS when the classification number is greater than 4, and the number of DMRS layer of the maximum orthogonal CDM in each RE set is 4. In Fig. 1, the left diagram is the DMRS diagram that supports a normal subframe, and the middle diagram and the right diagram are diagrams of the DMRS that supports a specific subframe.
According to the DMRS mapping shown in Fig. 1, a mixed multiplexing of Frequency Division Multiplexing (FDM) and CDM is introduced. Therefore, the transmission of powers corresponding to the different layers of the resource element to support the DMRS may be different when the total number of layers is odd, and when the transmit power with the total number of layers is 2 it is different than when the number of layers total layers is even, but excluding 2. SUMMARY
In view of this, the main objective of the present disclosure is to provide a method and equipment for configuring the transmit power of a demodulation reference signal, which is capable of performing channel estimation without waiting for notification from the network side.
To achieve the above purpose, the technical solution of the present disclosure is made by: a method for setting the transmit power for a demodulation reference signal, and the method includes: the ratio between the transmit power of the DMRS in each layer of a DMRS RE and the transmit power of data at a corresponding layer in a data RE is set to be a constant value.
Preferably, the method may further include: the transmit power of the DMRS at each layer of the same RE is configured for the same.
Preferably, the method may further include: different constant values are set for the different numbers of total layers used in downlink transmission; or a unique constant value is established for the different numbers of total layers used in downlink transmission.
Preferably, the step of establishing different constant values for the different numbers of total layers used in downlink transmission can specifically include: a first constant value is set when the total number of layers used in downlink transmission is less than or equal to 2; and a second constant value is set when the total number of layers used in downlink transmission is greater than or equal to 3.
Preferably, the method may further include: mapping the DMRS at one layer over two DMRS ports when the total number of layers used in downlink transmission is greater than or equal to 3 and is odd.
Equipment for configuring transmission power for DMRS, and the equipment includes: a configuration unit for configuring the relationship between the transmit power of a DMRS in each layer of a DMRS RE and the data transmission power in a corresponding layer in a data RE to be constant value.
Preferably, the setting unit is further used for setting the transmit power of the DMRS at each layer of the same RE to the same.
Preferably, the equipment may further include: an establishing unit for establishing different constant values for the different numbers of total layers used in downlink transmission; or for establishing a unique constant value for the different numbers of total layers used in downlink transmission.
Preferably, the establishment unit is further used for establishing a first constant value when the total number of layers used in downlink transmission is less than or equal to 2; and setting a second constant value when the total number of layers used in downlink transmission is greater than or equal to 3.
Preferably, the equipment may further include: a mapping unit for mapping the DMRS at one layer over two DMRS ports when the total number of layers used in downlink transmission is greater than or equal to 3 and is odd.
Preferably, the constant value is a natural number less than or equal to 4.
In the present disclosure, the ratio between the DMRS transmit power in each layer of an RE and the data transmission power in a corresponding layer is set to be a constant value, and the constant ratio is set at the user terminal. Therefore, the network side does not need to notify the user terminal of the corresponding relationship between the DMRS transmit power in each layer and the data transmission power in the corresponding layer, which simplifies blocking of control signaling on the network side . As the corresponding relationship between DMRS transmit power and data transmission power at each layer is configured at the user terminal, the user terminal can estimate channels without waiting for notification from the network side, which improves the efficiency of channel estimation. BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 shows a diagram of DMRS supporting a normal subframe and a specific subframe with normal CP in the LTE_A system;
Fig. 2 shows the first structure of the apparatus for setting the transmit power of the demodulation reference signal in the present disclosure;
Fig. 3 shows the second structure of the apparatus for setting the transmit power of the demodulation reference signal in the present disclosure; and
Fig. 4 shows the third structure of the apparatus for setting the transmit power of the demodulation reference signal in the present disclosure. DETAILED DESCRIPTION
The basic concept of the present disclosure is that: the ratio between the DMRS transmit power in each layer of a DMRS RE and the data transmission power in a corresponding layer in a data RE is configured to be a constant value, and the constant relationship is established at the user's terminal. Therefore, the network side does not need to notify the user terminal of the corresponding relationship between the DMRS transmit power in each layer and the data transmission power in the corresponding layer, which simplifies blocking of control signaling on the network side .
For clarification of the solutions and technical advantages of the present disclosure, the present disclosure is described in detail below with reference to the accompanying drawings and embodiments.
In the present disclosure, the DMRS resource element refers to a resource element of the transmission DMRS, and the data resource element refers to a resource element for performing the transmission of traffic data. As shown in Fig. 1, grids covered with sand dots and crosshairs in the diagram are the resource elements for DMRS support, and blank grids are the resource elements for data support.
In the present disclosure, the total transmit power of the resource element corresponding to the demodulation reference signal is configured so that the ratio between the transmit power of the DMRS in each layer in the resource element and the transmit power of the data in the layer corresponding is set to be a constant value. That is, the total transmit power in the DMRS resource element is determined according to the ratio between the DMRS transmit power at each layer in the DMRS resource element and the data transmission power at each layer in the DMRS resource element. Dice.
At least one DMRS layer can be created on each DMRS resource element. In general, the maximum number of DMRS layers in the DMRS resource element for performing Code Division Multiplexing is 4 according to the current characteristic of the system. Data from all tiers that match the current total number of tiers is created in the data resource element. In the present disclosure, the DMRS transmit power in each layer of each resource element is the same, and the data transmission power in each layer in each resource element is also the same. In the present disclosure, the ratio between the DMRS transmit power at each layer in the resource element and the data transmission power at the corresponding layer is configured to be a constant value. Therefore, the relationship between the data transmission power at each layer and the DMRS transmission power at each layer does not need to be notified to the user terminal, which greatly saves the blocking of control signaling on the network side and even improves the efficiency of the user terminal channel estimation.
Two configuration modes are considered in this disclosure:
Mode 1: The ratio between the DMRS transmit power at each layer and the data transmit power at the corresponding layer is a constant r value, no matter what the total number of current layers used in downlink transmission. When the total transmit power of the RE data is P, the total transmit power of the DMRS RE is
, where Leo is the current total number of layers used in downlink transmission, and 1 is the number of layers of the DMRS Code Division Multiplexing in the DMRS RE.
Mode 2: the relationship between the DMRS transmit power in each layer and the data transmit power in the corresponding layer is respectively established according to the current total number of layers used in the downlink transmission. When the number of layers is less than or equal to 2, the above relationship is a constant value rl; if the constant value is set to 1, the total transmit power of the DMRS RE is only set to the same as the total transmit power of the RE data. When the number of layers is greater than or equal to 3, the above ratio is a constant value r2, for example, r2 can be 2. When the total transmission power of RE data is P, the power of , Lrlp Lrlp total transmission of the DMRS RE and
, where Leo current total number of layers used in downlink transmission, 1 is the number of layers of the DMRS Code Division Multiplexing in the DMRS RE.
The constant value above is generally a natural number less than 4.
The essence of the technical solution of the present disclosure is further described below by means of specific embodiments. Achievement 1
In the embodiment, it is assumed that each layer is designated with a fixed DMRS antenna port. For example, when the current DMRS ports are {port® , portl , port2 , port! , port4 , portS , port, portl } and the rating is 1 or 2, the pilot frequency sequence (DMRS) corresponding to the DMRS ports are mapped to the DMRS ports by Code Division Multiplexing, where the corresponding relationship between the sequence DMRS on each layer and each DMRS port is: layer® θ port® , and layerX θ port .
When the rating is 3 or 4, Code Division Multiplexing + Frequency Division Multiplexing/Time Division Multiplexing are done for the sequence of pilot frequencies corresponding to the DMRS ports, where Code Division Multiplexing is done for the sequence of pilot frequencies corresponding to port® and port , shown as sand point grids in Fig. 1 for the representation of RE, and Code Division Multiplexing is done for the sequence of pilot frequencies corresponding to portze port! , shown as grids of crosshairs in Fig. 1 for the RE representation.
When the rating is 5 to 8, Multiplexing of
Code Division + Frequency Division Multiplexing/Time Division Multiplexing are done on the pilot frequency sequence corresponding to the DMRS ports, where the Code Division Multiplexing is done for the pilot frequency sequence corresponding to port0, port1, port4 , portf>, shown as sand point grids in Fig. 1 for the RE representation, and Code Division Multiplexing is done for the pilot frequency sequence corresponding to port2 , port's , ports, port! , shown as grids of crosshairs in Fig. 1 are representing RE.
Based on a fixed DMRS antenna port corresponding to each layer, the relationship between the total transmit power of DMRS RE and the total transmit power of each data RE is shown in Table 1:


In Table 1, r represents the relationship between the DMRS transmit power in each layer and the data transmission power in the corresponding layer after configuration, and P represents the total transmission power of the RE data; the RE corresponding to the layer of the first CDM group is particularly the RE represented by the sand dot grids shown in Fig. 1, and the RE corresponding to the layer of the second CDM group is particularly the RE represented by the crosshair grids shown in Fig. 1. Taking the condition that Class is 5 and r is 2 in Table 1 as an example, the total transmit power of the RE corresponding to the layer of the first CDM group is . Since three layers (layerO, layerl, layer4) of DMRS are created in the RE and the DMRS transmit power at each layer in the RE is the same, the DMRS transmit power at each layer is 2 -P . As five data layers are created in the data RE and 5 the total transmit power of the RE data is P, therefore the data transmission power in each layer is ±P.
Consequently, the transmit power of the DMRS at each layer in the DMRS RE is guaranteed to be twice the transmission power corresponding to the data in the layer.
For the total RE transmit power corresponding to the layer of the second CDM group is -P, as two DMRS layers (layer2, layer3) are created in the RE, the DMRS transmit power in each layer in the RE is also the same ; therefore, the DMRS transmit power at each layer 2 is -P. Five data layers are created in the 5 data RE and the total transmit power of the RE data is P, so the transmit power of the data in each layer is
Consequently, the transmit power of the DMRS at each layer in the DMRS RE is guaranteed to be twice the transmission power corresponding to the data in the layer.
It is clarified that Table 1 assumes that the number of layers mapped to the RE of the first group of DMRS is greater than or equal to the number of layers mapped to the RE of the second group of DMRS. When the number of layers mapped to the RE of the first DMRS group is less than or equal to the number of layers mapped to the RE of the second DMRS group, the total power of the RE corresponding to the first CDM port group and the power can be interchanged. total RE corresponding to the second group of CDM ports in Table 1. Achievement 2
In the realization, when there are odd layers, the DMRS of a given layer is mapped to two DMRS ports simultaneously so that the number of DMRS ports is even. For example, it is assumed that there are I layers such as layerO, layerl, ... , I ayerl . When I is an odd number, the DMRS corresponding to a given layer/ is mapped to two DMRS ports simultaneously. For example, assume the number of layers is 3, the DMRS corresponding to layer 0 can be mapped to two DMRS ports simultaneously, as layer0 and layer1 correspond to a group of DMRS ports, and layer 0 and layer 2 correspond to another group of DMRS ports.
The relationship between the total transmit power of the DMRS RE and the total transmit power of each data RE is shown in Table 2.
Based on the mapping relationship between the above layers and the DMRS antenna ports, the relationship between the total transmit power of the DMRS RE and the total transmit power of each data RE is shown in Table 2:
In Table 2, r represents the relationship between the DMRS transmit power in each layer and the data transmit power in the corresponding layer after configuration, and P represents the total transmit power of the RE data. In the realization, for each class value, the total transmit power of the RE represented by the sand dot grids and that represented by the crosshair grids in Fig. 1 are configured to be the same.
Taking the condition that Rank is 5 and r is 2 in Table 1 as an example, the total transmit power of the DMRS RE is . As a given DMRS layer is mapped to two DMRS ports simultaneously, three DMRS layers are created in the REs represented by the sand dot grids and represented by the crosshair grids in Fig. 1. As the DMRS transmit power in each layer on the RE is the same, so the transmit power of the DMRS at every 2nd layer on the DMRS RE and -P. As five data layers are created in the data RE and the total transmit power of the data RE is P, therefore the transmit power of the data in each layer is ^P. Consequently, the transmit power of the DMRS at each layer in the DMRS RE is guaranteed to be twice the transmission power corresponding to the data in the layer.
Fig. 2 shows the first structure of the apparatus for the transmission power configuration for the demodulation reference signal in the present disclosure. As shown in Fig. 2, the apparatus for setting the transmit power for the demodulation reference signal in the example comprises a setting unit 20, which is used for setting the ratio between the transmit power of the DMRS at each layer in the DMRS RE is the data transmission power at the corresponding layer in the data RE as a constant value. In particular, the setting unit 20 is used for setting the transmit power of the DMRS at each layer of the same RE to be the same.
Fig. 3 shows the second structure of the apparatus for the transmission power configuration for the demodulation reference signal in the present disclosure. As shown in Fig. 3, based on the equipment shown in Fig. 2, the equipment for setting transmission power for the demodulation reference signal in the example further comprises: a setting unit 21, which is for setting different constant values for the different numbers of total layers used in downlink transmission, or establishing a unique constant value for the different numbers of total layers used in downlink transmission. The setting unit 21 is further used for setting a first constant value when the total number of layers used in downlink transmission is less than or equal to 2, and setting a second constant value when the total number of layers used in transmission of downlink is greater than or equal to 3.
Fig. 4 shows the third structure of the apparatus for setting the transmit power for the demodulation reference signal in the present disclosure. As shown in Fig. 4, based on the equipment shown in Fig. 2 or Fig. 3 (the example is based on Fig. 2), the equipment for setting the transmit power for the demodulation reference signal in the example still comprises : a mapping unit 22, which is for mapping DMRS at one layer over two DMRS ports when the total number of layers used in downlink transmission is greater than or equal to 3 and is odd.
The constant values above are natural numbers less than or equal to 4.
Those skilled in the art should understand that the equipment for setting the transmit power for the demodulation reference signal shown in Fig. 2, Fig. 3 and Fig. 4 is designed to constitute the above method for setting the transmit power for the demodulation reference signal, wherein the function of each unit in the equipment shown in Fig. 2, Fig. 3 and Fig. 4 can be understood as a reference to the above method description, and the function of each unit can be constituted by means of a program in a processor and can also be constituted by means of a specific logic circuit.
The foregoing concerns only preferred embodiments of the present disclosure and is not intended to limit the scope of protection of the present disclosure.

权利要求:
Claims (6)
[0001]
1. METHOD FOR CONFIGURING TRANSMISSION POWER FOR A DEMODULATION REFERENCE SIGNAL (DMRS), characterized in that it comprises: the configuration of a relationship between the transmission power of a DMRS in each layer of a DMRS Resource Element (RE) and the data transmit power at a corresponding layer in a data RE to be a constant value to set the total transmit power of the DMRS RE that corresponds to the DMRS; wherein the ratio is configured to be a constant value comprising: setting different constant values for the different numbers of total layers used in downlink transmission, or setting a unique constant value for the different numbers of total layers used in transmission downlink; wherein establishing different constant values for the different numbers of total layers used in downlink transmission further comprises: when the rating is 5 to 8, using Code and Frequency Division Multiplexing/Time Division Multiplexing between the difference of DMRS ports, where Code Division Multiplexing is done for the pilot frequency sequence corresponding to port 0 , port 1 , port 4 and port 6 , and Code Division Multiplexing is done for the pilot frequency sequence corresponding to port 2 , port3 , port5 , port 7 ; establishing a first constant value when the total number of layers used in downlink transmission is less than or equal to 2; and setting a second constant value when the total number of layers used in downlink transmission is greater than or equal to 3; where the constant value is set to equal the value of the second constant when the total number of layers used in downlink transmission is greater than or equal to 5.
[0002]
2. METHOD, according to claim 1, characterized in that it further comprises: setting the DMRS transmission power in each layer of the same RE for the same.
[0003]
3. METHOD, according to claim 1, characterized in that it further comprises: mapping the DMRS in a layer over two DMRS ports when the total number of layers used in the downlink transmission is greater than or equal to 3 and is odd.
[0004]
4. EQUIPMENT FOR CONFIGURING TRANSMISSION POWER FOR DEMODULATION REFERENCE SIGNAL (DMRS), characterized in that it comprises: a configuration unit for configuring a relationship between the transmit power of a DMRS in each layer of a DMRS Resource element (RE) and the data transmission power in a corresponding layer in a data RE to be constant value to set the total transmit power of the DMRS RE that corresponds to the DMRS; a setting unit for establishing different constant values for the different numbers of total layers used in downlink transmission; or establishing a unique constant value for the different numbers of total layers used in downlink transmission; wherein additionally the establishment unit for establishing a first constant value when the total number of layers used in downlink transmission is less than or equal to 2; and setting a second constant value when the total number of layers used in downlink transmission is greater than or equal to 3; where the constant value is set to equal the value of the second constant when the total number of layers used in downlink transmission is greater than or equal to 5.
[0005]
5. EQUIPMENT, according to claim 4, characterized in that the configuration unit is still used for the configuration of the DMRS transmission power in each layer of the same RE for the same.
[0006]
6. EQUIPMENT according to claim 4, further comprising: a mapping unit for mapping the DMRS in a layer over two DMRS ports when the total number of layers used in downlink transmission is greater than or equal to 3 and is odd.

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CN106487474B|2015-08-24|2019-08-23|电信科学技术研究院|A kind of downlink data demodulation method and device|

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CN107181579A|2016-03-11|2017-09-19|北京信威通信技术股份有限公司|A kind of descending DMRS resource multiplexing methods|

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WO2018021825A1|2016-07-26|2018-02-01|엘지전자 주식회사|Uplink signal transmission method and user equipment, and uplink signal reception method and base station|

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CN111147219B|2017-03-23|2021-03-09|Oppo广东移动通信有限公司|Method and device for transmitting uplink demodulation reference signal|

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CN110771215A|2017-08-04|2020-02-07|南通朗恒通信技术有限公司|Method and device used in user and base station of wireless communication|

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CN109660323B|2017-10-11|2020-10-20|维沃移动通信有限公司|Method, base station and user terminal for configuring time domain position of CSI-RS|

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CN111049628A|2018-10-12|2020-04-21|华为技术有限公司|Data transmission method and communication device|

法律状态:
2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-01-28| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-04-13| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-06-15| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 20/10/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF |

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2021-07-06| B16C| Correction of notification of the grant [chapter 16.3 patent gazette]|Free format text: REF. RPI 2632 DE 15/06/2021 QUANTO AO INVENTOR. |

优先权:

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申请号 | 申请日 | 专利标题

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CN2010101164119|2010-02-10|

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CN201010116411.9A|CN102148659B|2010-02-10|2010-02-10|The transmit power collocation method and device of demodulated reference signal|

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PCT/CN2010/077913|WO2011097894A1|2010-02-10|2010-10-20|Transmission power configuration method and apparatus for demodulation reference signal|

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