• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a method for optimizing channel power allocation in a wideband code division multiple access wireless subscriber network system, and particularly, in a wideband code division multiple access wireless subscriber network system which allocates necessary channel power to optimize wireless capacity and coverage of the system. Relates to a method for optimizing channel power allocation. In a preferred embodiment of the present invention, the optimal traffic channel power allocation ratio in the reverse direction is calculated by the following equation, here : Power ratio allocated to global pilot channel Reverse Frequency Reuse Efficiency The optimal APC channel power allocation ratio in the reverse direction is calculated by The optimal OW channel power allocation ratio in the reverse direction is calculated by The optimal SBCCH channel power allocation ratio in the forward direction is calculated by here : Power ratio allocated to global pilot channel Forward Frequency Reuse Efficiency The optimal FBCCH channel power allocation ratio in the forward direction is calculated by The optimal traff channel power allocation ratio in the forward direction is calculated by The optimal APC channel power allocation ratio in the forward direction is calculated by The optimal APC channel power allocation ratio in the forward direction is calculated by
    公开号:KR20000060340A
    申请号:KR1019990008557
    申请日:1999-03-15
    公开日:2000-10-16
    发明作者:임영식;위평환
    申请人:윤종용;삼성전자 주식회사;
    IPC主号:
    专利说明:

    Method for optimizing channel power allocation in B-CDMA WLL system in wideband code division multiple access wireless subscriber network system
    The present invention relates to a method for optimizing channel power allocation in a wideband code division multiple access wireless subscriber network system, and particularly, in a wideband code division multiple access wireless subscriber network system which allocates necessary channel power to optimize wireless capacity and coverage of the system. Relates to a method for optimizing channel power allocation.
    Typically, a Code Division Multiple Access (CDMA) reverse channel consists of an access channel and a traffic channel, which allows the mobile station to initiate communication with the base station or in response to a paging channel message sent by the base station. Used to send
    In IS-95, up to 32 access channels can be provided for one forward paging channel, and the information data rate of the access channel is 4800bps.
    The reverse traffic channel operates at four kinds of variable data rates in the same way as the forward traffic channel, and each channel of the access channel and the traffic channel is distinguished by a unique user long period code.
    The CDMA forward channel consists of a pilot channel, a synchronization channel, up to seven paging channels, and up to 63 traffic channels, which allow the mobile station to acquire timing for the CDMA forward channel, i. A phase reference for runt demodulation is provided, and the mobile station is provided with a means to compare the strength of signals from nearby base stations to determine handoff.
    The synchronization channel operates at 1200bps and sends a synchronization message to the terminal to adjust the absolute time between the base station and the mobile station.The mobile station can demodulate the paging channel accurately by notifying the bit information rate of the paging channel. It is also used to inform the same control information and to call a specific mobile station.
    In the traffic channel, a variable data rate voice signal of 9600, 4800, 2400, and 1200bps is transmitted, and signaling information in a call is multiplexed and transmitted.
    1 is a block diagram of a general reverse traffic channel. As shown in FIG. 1, a reverse traffic channel is composed of a frame length of 20 ms, one frame is composed of 16 power control groups having a length of 1.25 ms, and user data is constrained. Through a convolutional encoder 10 having a length K of 9 and a code rate of 1/3, iteratively 11 and interleaving 12 according to the data rate and then 64-ary orthogonal modulation 13.
    When the reverse traffic channel is not 9600bps, data is transmitted only during the selected power control group with the same power. Thus, data is transmitted in a form intermittent according to the data rate. Determined by the optimizer 15.
    It is then scrambled at a rate of 1.2288 MHz with a long period PN code of 2 42 -1 long periods, and then offset QPSK modulated with two short period pilot PN code pairs.
    2 is a block diagram of a general forward traffic channel. As shown in FIG. 2, the forward traffic channel has a frame length of 20 ms, one frame consists of 16 power control groups having a length of 1.25 ms, and user data is constrained. Through a convolutional encoder 20 having a length K of 9 and a code rate of 1/2, iterations 21 and interleaving 22 are carried out in accordance with the data rate.
    It is then scrambled into a long period PN code, and only one of the 64 orthogonal Walsh codes is multiplied to spread to a signal of 1.2288 Mcps, which is multiplied by two PN code pairs and transmitted QPSK modulated.
    Meanwhile, in the conventional CDMA wireless local loop (WLL), power allocation of each wireless channel of a base station and a terminal station is not properly performed, and thus, it is difficult to satisfy a desired performance requirement of each channel. The optimization of is not easy to implement, and there is a problem that coverage imbalance occurs in the forward and reverse directions.
    Accordingly, an object of the present invention, which is designed to solve the problems of the prior art operating as described above, is to allocate the required channel power to satisfy the desired performance requirements of each channel, to maximize the radio capacity and coverage of the system, and to forward and reverse To provide a method for optimizing channel power allocation in a wideband code division multiple access wireless subscriber network system that balances the coverage of the network.
    Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.
    1 is a block diagram of a general reverse traffic channel.
    2 is a block diagram of a general forward traffic channel.
    <Description of the code | symbol about the principal part of drawing>
    10, 20: convolutional encoder 11, 21: symbol repeating unit
    12, 22: block interleaving 13: 64-ary orthogonal modulator
    14, 23: long cycle code generator
    15: Data Burst Randomizer
    16: delay 17a, 17b, 26a, 26b baseband filter
    24a, 24b: Desire Mate 25: Multiplexer
    Preferred embodiments according to the present invention created to achieve the object as described above,
    Obtaining quality requirements for each radio channel in the forward and reverse directions through a performance test of the CDMA system; and
    Power ratio allocated to global pilot channel to obtain power allocation ratio in the reverse direction, RSC propagation path loss at a certain distance from RNT, transmit antenna gain of RNT, receive antenna gain of RNT, reverse frequency reuse efficiency, RNT transmit power Obtaining propagation path loss of the pilot channel from an active user;
    Maximum allowable path loss in the pilot channel and the traffic channel Obtaining from the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the maximum power ratio assigned to the traffic channel, the E b / N o requirement and processing gain of each channel as variables;
    Obtaining a maximum power ratio assigned to the APC channel, with the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the E b / N o requirement and processing gain of each channel as variables;
    Obtaining a maximum power ratio assigned to the OW channel, with the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the E b / N o requirement and processing gain of each channel as variables;
    Also, to find the power allocation ratio in the forward direction,
    Power ratio assigned to global pilot channel, RNT propagation path loss at some distance from RSC, transmit antenna gain of RSC, receive antenna gain of RNT, forward frequency reuse efficiency, RNT transmit power, pilot from active user Obtaining propagation path loss of the channel;
    Maximum allowable path loss value on pilot channel and reception of SBCCH channel Obtaining a maximum power ratio allocated to the SBCCH channel from;
    Maximum allowable path loss value on pilot channel and reception of FBCCH channel Obtaining a maximum power ratio allocated to the FBCCH channel from;
    Maximum allowable path loss value on pilot channel and traffic channel reception Obtaining a maximum power ratio allocated to the traffic channel from;
    Maximum allowable path loss value on pilot channel and reception of APC channel Obtaining a maximum power ratio allocated to the APC channel from;
    Maximum allowable path loss value on pilot channel and reception of OW channel A method of allocating channel power for optimizing radio capacity and coverage of a CDMA system, comprising: obtaining a maximum power ratio allocated to an OW channel from.
    Here, the optimal traffic channel power allocation ratio in the reverse direction is calculated by the following equation.
    here : Power ratio allocated to global pilot channel
    Reverse Frequency Reuse Efficiency
    remind Is calculated by the equation
    remind The equation calculates the propagation path loss of the pilot channel.
    remind Is calculated by the equation
    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RCS with distance r from RNT
    : Transmit Antenna Gain of RNT
    : Receive Antenna Gain of RCS
    Reverse Frequency Reuse Efficiency
    RNT transmit power
    Active users
    remind Calculate the maximum path loss of the reverse link.
    Of the traffic channel Is calculated by the equation
    here : Power ratio allocated to traffic channel
    : Data transmission rate of traffic channel
    The optimal APC channel power allocation ratio in the reverse direction is calculated by the following equation.
    Of the APC channel Is calculated by the equation
    here : Power ratio allocated to APC channel
    : Data rate of APC channel
    The optimal OW channel power allocation ratio in the reverse direction is calculated by the following equation.
    Of the OW channel Is calculated by the equation
    here : Power ratio allocated to OW channel
    : OW channel data transmission rate
    The optimal SBCCH channel power allocation ratio in the forward direction is calculated by the following equation.
    here : Power ratio allocated to global pilot channel
    Forward Frequency Reuse Efficiency
    remind Is calculated by the equation
    remind The equation calculates the propagation path loss of the pilot channel.
    remind Is calculated by the equation
    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RNT with distance r from RCS
    : Transmit Antenna Gain of RCS
    : RNT's Receive Antenna Gain
    Forward Frequency Reuse Efficiency
    RNT transmit power
    remind Calculate the maximum path loss of the forward link.
    Of the SBCCH channel Is calculated by the equation
    here : Power ratio allocated to SBCCH
    : SBCCH data transmission rate
    The optimal FBCCH channel power allocation ratio in the forward direction is calculated by the following equation.
    Of the FBCCH channel Is calculated by the equation
    here : Power ratio allocated to FBCCH
    : FBCCH data transmission rate
    The optimal traff channel power allocation ratio in the forward direction is calculated by
    Of the traff channel Is calculated by the equation
    here : power ratio allocated to traff
    : Data transmission speed of traff
    The optimal APC channel power allocation ratio in the forward direction is calculated by
    Of the APC channel Is calculated by the equation
    here : Power ratio allocated to APC
    : APC data transfer rate
    The optimal APC channel power allocation ratio in the forward direction is calculated by
    Of the OW channel Is calculated by the equation
    here : Power cost allocated to OW
    : OW data transmission speed
    Hereinafter, described in detail with reference to the accompanying drawings, preferred embodiments of the present invention.
    In deriving the optimal channel power allocation ratio in the reverse and forward directions of the wireless subscriber network system, the quality requirements of each of the wireless channels in the reverse and forward directions are derived, and the quality requirements of the respective wireless channels are derived through system performance tests.
    First, the derivation process of the reverse power allocation ratio will be described.
    Calculate propagation path loss of pilot channel.
    [Equation 1]
    -Maximum path loss of reverse link
    [Equation 2]
    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RCS with distance r from RNT
    : Transmit Antenna Gain of RNT
    : Receive Antenna Gain of RCS
    Reverse Frequency Reuse Efficiency
    RNT transmit power
    Active users
    In the cell region defined as the reverse pilot channel, the reception Eb / Nt of the APC channel, the OW channel, and the traffic channel must satisfy certain requirements.
    Eb / Nt of the traffic channel
    [Equation 3]
    here : Power ratio allocated to traffic channel
    : Data transmission rate of traffic channel
    Substituting the maximum allowable path loss determined as the pilot channel in [Equation 2] into [Equation 3], the power cost to be allocated to the traffic channel is derived as in [Equation 4].
    [Equation 4]
    -In the same way, the maximum power ratios to be allocated to the APC channel and the OW channel are shown in [Equation 5] and [Equation 6].
    [Equation 5]
    [Equation 6]
    -From Equation 4 to Equation 6, the power allocation ratio of each channel is the E c / I t threshold of the pilot channel, the pilot channel power allocation ratio, and the E b / N o requirements and processing gains of each channel. gain).
    The derivation process of the forward power allocation ratio is described as follows.
    E c / I t of the pilot channel
    [Equation 8]
    -Maximum path loss of reverse link
    [Equation 9]
    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RNT with distance r from RCS
    : Transmit Antenna Gain of RCS
    : RNT's Receive Antenna Gain
    Forward Frequency Reuse Efficiency
    RNT transmit power
    In the cell region defined as the forward global pilot channel, the received Eb / Nt of the SBCCH, FBCCH, APC channel, OW channel, and traffic channel must satisfy certain requirements.
    -Eb / Nt of SBCCH:
    [Equation 10]
    here : Power ratio allocated to SBCCH
    : SBCCH data transmission rate
    Substituting the maximum allowable path loss determined as the global pilot channel of Equation 1 into Equation 4, the power ratio to be allocated to the SBCCH channel is derived as shown in Equation 11.
    [Equation 11]
    In the same manner, the maximum power ratios to be allocated to the FBCCH, the traffic channel, the APC channel, and the OW channel are shown in Equation 12, Equation 13, Equation 14, and Equation 15.
    [Equation 12]
    [Equation 13]
    [Equation 14]
    [Equation 15]
    An example of applying the channel power allocation method to an overseas wireless subscriber network system is as follows.
    First, measure the quality requirements of each channel.
    Reverse
    Data rate (Kbps)E b / N o Required and E c / I t ThresholdBERRemarks Traffic channel324 dB10-4See SP31370 (Ch. 3.5) APCCH64-0.5 dB0.2 OWCH165.5 dB10-7 pilot8320-20.6 dB
    Forward
    Data rate (Kbps)E b / N o Required and E c / I t ThresholdBERRemarks Traffic channel324 dB10-4See SP31370 (Ch. 3.5) APCCH64-0.5 dB0.2 OWCH165.5 dB10-7 SBCCH165.5 dB10-7 FBCCH165.5 dB10-7 pilot8320-14.6 dB
    The calculated result is as follows.
    Reverse
    channelPower allocationDigital gainRemarks Global pilot0.28514RNT maximum transmit power: 0.1 W traffic0.31320 APC0.22312 OW0.22217
    -Relation between channel power ratio and digital gain
    Equation 7-1
    [Equation 7-2]
    Equation 7-3
    In RNT, digital gain is a value for obtaining the power ratio between channels without representing an absolute transmission level.
    -The digital gain for each channel is calculated from the channel power ratio calculated in the above equation:
    = 20
    = = = 14
    = = = 14
    = = = 17
    Forward
    channelPower allocationDigital gainRemarks Global pilot0.035119RCS maximum transmit power: 35 W SBCCH0.006874 FBCCH0.006874 traffic0.009688 APC0.006837 OW0.006874
    Channel Power Allocation Ratio and Digital Gain
    -Maximum transmission power = 35W, so the output of each channel is as follows.
    = 119
    = = 74
    = = 74
    = = 88
    = = 37
    = = 74
    The present invention can be variously modified and can take various forms and only the specific embodiments thereof are described in the detailed description of the invention. It is to be understood, however, that the present invention is not limited to the specific forms mentioned in the detailed description of the invention, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to do.
    In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.
    The present invention can maximize the radio capacity and coverage of the system while satisfying the quality requirements of each channel by providing a power allocation method for each radio channel of the base station and the terminal station, and can balance the forward and reverse coverage. .
    权利要求:
    Claims (24)
    [1" claim-type="Currently amended] Obtaining quality requirements for each radio channel in the forward and reverse directions through a performance test of the CDMA system; and
    Power ratio allocated to global pilot channel to obtain power allocation ratio in the reverse direction, RSC propagation path loss at a certain distance from RNT, transmit antenna gain of RNT, receive antenna gain of RNT, reverse frequency reuse efficiency, RNT transmit power Obtaining propagation path loss of the pilot channel from an active user;
    Maximum allowable path loss in the pilot channel and the traffic channel Obtaining from the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the maximum power ratio assigned to the traffic channel, the E b / N o requirement and processing gain of each channel as variables;
    Obtaining a maximum power ratio assigned to the APC channel, with the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the E b / N o requirement and processing gain of each channel as variables;
    Obtaining a maximum power ratio assigned to the OW channel, with the E c / I t threshold of the pilot channel, the power ratio assigned to the pilot channel, and the E b / N o requirement and processing gain of each channel as variables. , Channel power allocation method for optimizing wireless capacity and coverage of CDMA system.
    [2" claim-type="Currently amended] The method of claim 1, wherein the power allocation ratio in the forward direction is obtained by
    Power ratio assigned to global pilot channel, RNT propagation path loss at some distance from RSC, transmit antenna gain of RSC, receive antenna gain of RNT, forward frequency reuse efficiency, RNT transmit power, pilot from active user Obtaining propagation path loss of the channel;
    Maximum allowable path loss value on pilot channel and reception of SBCCH channel Obtaining a maximum power ratio allocated to the SBCCH channel from;
    Maximum allowable path loss value on pilot channel and reception of FBCCH channel Obtaining a maximum power ratio allocated to the FBCCH channel from;
    Maximum allowable path loss value on pilot channel and traffic channel reception Obtaining a maximum power ratio allocated to the traffic channel from;
    Maximum allowable path loss value on pilot channel and reception of APC channel Obtaining a maximum power ratio allocated to the APC channel from;
    Maximum allowable path loss value on pilot channel and reception of OW channel And obtaining a maximum power ratio allocated to the OW channel from the channel power allocation method for optimizing radio capacity and coverage of the CDMA system.
    [3" claim-type="Currently amended] The method according to claim 1 or 2, wherein the APC channel, the OW channel, and the traffic channel in a cell region defined as a reverse pilot channel. A channel power allocation method for optimizing the radio capacity and coverage of a CDMA system, which satisfies a specific requirement.
    [4" claim-type="Currently amended] The method of claim 3, wherein the SBCCH channel, the FBCCH channel, the APC channel, the OW channel, and the traffic channel in a cell region defined as a forward global pilot channel. A channel power allocation method for optimizing the radio capacity and coverage of a CDMA system, which satisfies a specific requirement.
    [5" claim-type="Currently amended] 5. The method of claim 4, wherein the propagation path loss of the pilot channel in the reverse direction is obtained from the following equation.


    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RCS with distance r from RNT
    : Transmit Antenna Gain of RNT
    : Receive Antenna Gain of RCS
    Reverse Frequency Reuse Efficiency
    RNT transmit power
    Active users
    [6" claim-type="Currently amended] 6. The method of claim 5, wherein the maximum allowable path loss value in the reverse direction is obtained from the following equation.

    [7" claim-type="Currently amended] 7. The method of claim 6, wherein The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to traffic channel
    : Data transmission rate of traffic channel
    [8" claim-type="Currently amended] 8. The method of claim 7, wherein the maximum power ratio allocated to the traffic channel in the reverse direction is obtained from the following equation.

    here : Power ratio allocated to global pilot channel
    Reverse Frequency Reuse Efficiency
    [9" claim-type="Currently amended] 9. The method of claim 8, wherein the maximum power ratio allocated to the APC channel in the reverse direction is obtained from the following equation.

    [10" claim-type="Currently amended] 10. The apparatus of claim 9, wherein the APC channel is in the reverse direction. The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to APC channel
    : Data rate of APC channel
    [11" claim-type="Currently amended] 11. The method of claim 10, wherein the maximum power ratio allocated to the OW channel in the reverse direction is obtained from the following equation.

    [12" claim-type="Currently amended] 12. The system of claim 11, wherein in the OW channel in the reverse direction The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to OW channel
    : OW channel data transmission rate
    [13" claim-type="Currently amended] 13. The method of claim 12, wherein the propagation path loss of the pilot channel in the forward direction is obtained from the following equation.


    here : Power ratio allocated to global pilot channel
    : Propagation path loss of RNT with distance r from RCS
    : Transmit Antenna Gain of RCS
    : RNT's Receive Antenna Gain
    Forward Frequency Reuse Efficiency
    RNT transmit power
    [14" claim-type="Currently amended] 15. The method of claim 13, wherein the maximum allowable path loss value in the forward direction is obtained from the following equation.

    [15" claim-type="Currently amended] 15. The apparatus of claim 14, wherein the SBCCH channel in the forward direction. The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to SBCCH
    : SBCCH data transmission rate
    [16" claim-type="Currently amended] 16. The method of claim 15, wherein the maximum power ratio allocated to the SBCCH channel in the forward direction is obtained from the following equation.

    here : Power ratio allocated to global pilot channel
    Forward Frequency Reuse Efficiency
    [17" claim-type="Currently amended] 17. The apparatus of claim 16, wherein the FBCCH channel in the forward direction. The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to FBCCH
    : FBCCH data transmission rate
    [18" claim-type="Currently amended] 18. The method of claim 17, wherein the maximum power ratio allocated to the FBCCH channel in the forward direction is obtained from the following equation.

    [19" claim-type="Currently amended] 19. The apparatus of claim 18, wherein the traffic channel in the forward direction is The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : power ratio allocated to traff
    : Data transmission speed of traff
    [20" claim-type="Currently amended] 20. The method of claim 19, wherein the maximum power ratio allocated to the traffic channel in the forward direction is obtained from the following equation.

    [21" claim-type="Currently amended] 21. The apparatus of claim 20, wherein the APC channel in the forward direction. The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power ratio allocated to APC
    : APC data transfer rate
    [22" claim-type="Currently amended] 22. The method of claim 21, wherein the maximum power ratio allocated to the APC channel in the forward direction is obtained from the following equation.

    [23" claim-type="Currently amended] 23. The system of claim 22, wherein the OW channel in the forward direction. The channel power allocation method for optimizing the radio capacity and coverage of the CDMA system obtained from the following equation.

    here : Power cost allocated to OW
    : OW data transmission speed
    [24" claim-type="Currently amended] 24. The method of claim 23, wherein the maximum power ratio allocated to the OW channel in the forward direction is obtained from the following equation.
    类似技术:
    公开号 | 公开日 | 专利标题
    US9019940B2|2015-04-28|Method for using a base station to selectively utilize channels to support a plurality of communications
    US9913271B2|2018-03-06|Qualifying available reverse link coding rates from access channel power setting
    JP5123415B2|2013-01-23|Spread spectrum communication system that saves power consumption of transmitting and receiving stations when inactive
    Dahlman et al.1998|UMTS/IMT-2000 based on wideband CDMA
    EP0985283B1|2005-03-02|Device and method for exchanging frame messages of different lengths in a wireless communication system
    ES2622456T3|2017-07-06|Procedure and apparatus for transmitting packet data at high speed
    DE60115719T2|2006-06-29|Apparatus and method for switching transmission of a data control channel in a high data rate mobile communication system
    JP3869656B2|2007-01-17|Apparatus and method for performing handoff from asynchronous mobile communication system to synchronous mobile communication system
    US8005120B2|2011-08-23|Base station apparatus of mobile communication system
    AU766996B2|2003-10-30|Apparatus and method for determining a data rate of packet data in a mobile communication system
    RU2232472C2|2004-07-10|Method and device for transferring transmission format combination indicator for joint use of downlink channel in broadband mobile code-division multiple access communication system
    AU716705B2|2000-03-02|Subscriber unit for a CDMA wireless communication system
    US6438119B1|2002-08-20|Data communication device and method for mobile communication system with dedicated control channel
    US6747963B1|2004-06-08|Apparatus and method for gated transmission in a CDMA communication system
    US6917607B1|2005-07-12|Apparatus and method for gated transmission in CDMA communication system
    CA2184772C|1999-12-14|Code division multiple access system providing load and interference based demand assignment service to users
    JP4087316B2|2008-05-21|Data transmission method and mobile telephone system
    RU2415516C2|2011-03-27|Improved method for allocating radio resources
    EP1036437B1|2006-12-27|Methods and apparatuses for providing ternary power control in a communication system
    JP3961829B2|2007-08-22|Apparatus and method for intermittent transmission / reception of control channel signal in code division multiple access communication system
    DE10201270B4|2007-09-27|Method and apparatus for controlling transmission power in an NB-TDD CDMA communication system
    JP4202932B2|2008-12-24|CDMA signal power estimation apparatus and method
    JP4065353B2|2008-03-26|Apparatus and method for configuring a data channel for symmetric / asymmetric data transmission
    US6185246B1|2001-02-06|System and method for orthogonal spread spectrum sequence generation in variable data rate systems
    DE69736010T2|2006-10-05|Method for determining the position of remote units in a communication system
    同族专利:
    公开号 | 公开日
    KR100288381B1|2001-04-16|
    US6731620B1|2004-05-04|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    1999-03-15|Application filed by 윤종용, 삼성전자 주식회사
    1999-03-15|Priority to KR1019990008557A
    2000-10-16|Publication of KR20000060340A
    2001-04-16|Application granted
    2001-04-16|Publication of KR100288381B1
    优先权:
    申请号 | 申请日 | 专利标题
    KR1019990008557A|KR100288381B1|1999-03-15|1999-03-15|method for optimizing channel power allocation in B-CDMA WLL system|
    [返回顶部]