JP4066015B2 - Mobile communication base station equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a mobile communication base station apparatus, and more particularly to channel efficiency in a mobile communication base station apparatus of a CDMA (Code Division Multiple Access) cellular system that has a diversity transmission function in a transmission channel and uses spread modulation by QPSK. In next-generation mobile phone systems represented by IMT-2000, an increase in the number of channels per device and a reduction in device size are required in order to spread the system.
[0002]
[Prior art]
The conventional IMT-2000 mobile communication base station apparatus realizes space diversity and other various diversity using two transmission branches when performing diversity transmission, and one when not performing diversity transmission. The transmission branch of is stopped and unused.
[0003]
In addition, a synchronization channel (SCH) and a synchronization detection display channel (AICH: Acquisition Indicator Channel) are always provided so that a transmission channel can be assigned to a call from a user. Transmission is stopped during a time period when channel assignment is not performed, and the channel is not used.
[0004]
As a prior art document, transmission power control is performed by notifying the following Patent Document 1 regarding transmission diversity, and the following Patent Document 2 regarding switching diversity reception, by notifying the receiver type such as the presence / absence of diversity as a message indicating receiver performance. The means for performing is described in Patent Document 3 below.
[0005]
[Patent Document 1]
JP 2002-84258 A (paragraphs 0006, 0024)
[Patent Document 2]
JP-A-6-284062 (Claim 1 etc.)
[Patent Document 3]
JP-A-9-326753 (paragraphs 0023 and 0024)
[0006]
[Problems to be solved by the invention]
As described above, in a mobile communication base station apparatus such as an IMT-2000 system, when diversity transmission is not performed, one of the transmission branches is set to an unused state, and a channel used for transmission channel allocation or the like Since the transmission is stopped and in an unused state except when the transmission channel allocation process is executed, the channel is not used effectively and the channel utilization efficiency is low.
[0007]
The present invention makes it possible to maximize the use of a unique channel that can be used in each mobile communication base station apparatus and to increase the channel usage rate, thereby reducing the cost of the apparatus and increasing the number of channels per apparatus With the goal. Also, when diversity transmission cannot be performed due to restrictions such as the installation location of the mobile communication base station apparatus, it is possible to easily increase the number of channels without changing the diversity transmission circuit configuration as much as possible. For the purpose.
[0008]
Another object of the present invention is to review the conventional configuration using 16 channels with the synchronization detection display channel (AICH) always in a transmission state, and to effectively use channels used only when executing transmission channel assignment processing. To do. It is another object of the present invention to make effective use of the transmission idle time of the synchronization channel (SCH).
[0009]
[Means for Solving the Problems]
The mobile communication base station apparatus according to the present invention is (1) in a mobile communication base station apparatus of a spread spectrum modulation type cellular communication system having a diversity transmission function in each transmission channel. The transmission branch selection means for switching to the spread modulation unit corresponding to each transmission branch of each transmission channel by switching at the time of implementation, and when performing diversity transmission to the spread modulation unit corresponding to the transmission branch, And a spreading code generator for outputting different spreading codes corresponding to transmission data.
[0010]
Also, (2) means for spreading and modulating the synchronization detection display channel in units of transmission branches of each transmission channel, and channel selection for assigning the synchronization detection display channel modulated wave to the transmission channel by selecting a transmission channel that is not in use Means.
[0011]
(3) In a configuration for generating a synchronization channel modulated wave, means for transmitting data with zero transmission power to a free area after the synchronization channel data to be transmitted, the synchronization channel data and subsequent data with zero transmission power Means for performing spreading modulation with a spreading code, and spreading code generating means for continuously sending out the spreading code without stopping transmission even during the sending period of the data with zero transmission power. .
[0012]
(4) In the configuration of the synchronization channel data transmission unit using time-switching transmission diversity in which synchronization channel data is transmitted alternately from different transmission branches for each slot, the transmission power is transmitted to the slot next to the slot transmitting the synchronization channel data. Means for transmitting zero data, means for performing spread modulation on a slot for transmitting the synchronization channel data and subsequent data slot for zero transmission power by a spreading code, and a transmission period for the zero transmission power data And spreading code generation means for continuously sending out the spreading code without stopping.
[0013]
Further, (5) means for transmitting a plurality of packet data to the free area after the synchronization channel data and data with zero transmission power to the subsequent free area, and the synchronization channel data when transmitting the synchronization channel data by time switching transmission diversity Means for transmitting a plurality of packet data and data with zero transmission power to a free space thereafter to a slot not transmitting data, and spreading modulation is performed on the packet data and subsequent data with zero transmission power by a spreading code. And spreading code generation means for continuously transmitting the spreading code without stopping the spreading code transmission even during the transmission period of the zero transmission power data.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an embodiment of the present invention that effectively uses a diversity transmitter. The mobile communication base station apparatus of this embodiment includes two transmission branches (BR0, BR1) for diversity transmission in a total of X channels from the first channel (Ch1) to the Xth channel (ChX), Spreading unit 1-3 for each channel branch (Ch1_BR0, Ch1_BR1, to ChX_BR0, ChX_BR1) _Ten ~ 1-3 _X1 Is provided.
[0015]
Each transmission data output from the data storage unit 1-1 is transmitted to the spreading unit 1-3. _Ten ~ 1-3 _X1 Each spreading unit 1-3 in accordance with a diversity (Div) control signal indicating whether or not to perform diversity transmission. _Ten ~ 1-3 _X1 A branch selection unit 1-2 is provided so as to be distributed selectively.
[0016]
Each diffusion part 1-3 _Ten ~ 1-3 _X1 Is transmitted by multiplying the transmission data output from the branch selection unit 1-2 and the channelization spreading code output from the spreading code generating unit 1-6, and then spreading the transmission data. _Ten ~ 1-4 _X1 To the transmission power control unit 1-4. _Ten ~ 1-4 _X1 Outputs a spread modulated wave with the instructed transmission power.
[0017]
Phase adjuster 1-5 ₁ , 1-5 _X Is provided in the transmission branch (BR1) of each channel (Ch1 to ChX), and according to the diversity (Div) control signal, the phase rotation according to the 3GPP standard is applied only to the signal on the transmission branch (BR1) side when performing diversity transmission. Do it. When the diversity transmission is not performed, the phase is fixed, and the input signal is output without rotating.
[0018]
The spreading code generator 1-6 receives each spreading unit 1-3 in response to a diversity (Div) control signal. _Ten ~ 1-3 _X1 Send spreading code to When performing diversity transmission, a spreading code unique to each channel (Ch1 to ChX) is transmitted in common to its transmission branch (BR0, BR1). On the other hand, when diversity transmission is not performed, a different spreading code is transmitted for each channel (Ch1 to ChX) and for each transmission branch (BR0, BR1).
[0019]
FIG. 2 shows the configuration of the branch selection unit 1-2 of the present invention. Assume that the number of channels is four. Transmission data output from each transmission branch (BR0, BR1) of each channel (Ch1 to Ch4) is selected by the selection units SEL1 to SEL7 in accordance with a diversity (Div) control signal.
[0020]
When performing diversity transmission, the selection units SEL1 to SEL7 select transmission data of each channel (Ch1 to Ch4) and output from each transmission branch (BR0, BR1) of each channel (Ch1 to Ch4). On the other hand, when the diversity transmission is not performed, the transmission data of the channels (Ch1 to Ch4) and the other channels (Ch (X-3) to ChX) are selected and the transmission branches (BR0, Ch4) of the channels (Ch1 to Ch4) are selected. From BR1).
[0021]
For example, transmission data of channel Ch2 will be described. When diversity transmission is performed, transmission data of channel Ch2 is selected by the selection units SEL2 and SEL3, and is transmitted as data for spreading of the transmission branches BR0 and BR1 of channel CH2. The On the other hand, when the diversity transmission is not performed, the transmission data of the channel Ch2 is selected by the selection unit SEL1 and transmitted as data for spreading of the transmission branch BR1 of the channel CH1.
[0022]
FIG. 3 shows the configuration of the spread code generator 1-6. The spreading code generation unit 1-6 includes two channelization code storage units 3-1 and 3-2 so that a channelization code can be generated for each transmission branch. Then, according to the diversity (Div) control signal, when performing diversity transmission, the selection unit SEL1 selects the channelization spreading code of the transmission branch BR0 and outputs it from the transmission branch BR1, and the same channelization spread from the transmission branches BR0 and BR1. Send code data.
[0023]
On the other hand, when diversity transmission is not performed, the selection unit SEL1 selects the channelization spreading code of the transmission branch BR1, outputs it from the transmission branch BR1, and sends different channelization spreading code data from the transmission branches BR0 and BR1, respectively.
[0024]
Next, FIG. 4 shows an embodiment of the present invention in which the synchronization detection display channel (AICH) is effectively used. This embodiment is a diffusion unit diffusion unit 1-3 in the embodiment of FIG. _Ten ~ 1-3 _X1 A selection unit SEL1 that selects transmission data (spread modulation wave) output from the AICH processing unit 4-1 and a signal of the synchronization detection display channel (AICH) output from the AICH processing unit 4-1. ₀ , SEL1 ₁ , ~ SELX ₀ , SELX ₁ Is added to the embodiment of FIG.
[0025]
The synchronization detection display channel (AICH) is standardized by a standardization organization called 3GPP, and is synchronized from the mobile radio base station apparatus as a response to the RACH (Random Access Channel) preamble signal transmitted from the mobile terminal when the radio link is connected. It is used as a channel for transmitting detection indication signals and has 16 signature patterns.
[0026]
FIG. 5 shows the configuration of the AICH processing unit 4-1. The signature selection unit 5-1 selects a response pattern for the Ack signal received from the uplink, and the AICH spreading unit 5-2 ₁ 5-2 ₁₅ To send. AICH diffusion section 5-2 ₁ 5-2 ₁₅ The channel selection unit 5-3 selects which transmission channel the Ack signal spread-modulated for each transmission branch is transmitted.
[0027]
FIG. 6 shows a detailed configuration diagram of the channel selector 5-3. As shown in the figure, the channel selection unit receives transmission data of ACK1 to ACK15 of the transmission branch BR0, selects one of them and outputs it, and ACK1 to ACK15 of the transmission branch BR1. Are selected, and one of them is selected and output (BR1_Ch1_SEL to BR1_ChX_SEL), and a route selection unit 6-1 for notifying the selection unit of transmission data designation information to be selected. .
[0028]
The route selection unit 6-1 inputs an enable signal (ACK1_EN to ACK15_EN) of transmission data of each ACK1 to ACK15 and instruction information indicating that each transmission channel (Ch1 to ChX) is in use (ON), Based on the input information, the selection information (BR0_Ch1_SEL to BR0_ChX_SEL, BR1_Ch1_SEL to BR1_ChX_SEL) of the selection of transmission data to be selected is notified.
[0029]
As the selection means in the route selection unit 6-1_, a route selection truth table (No. 1) shown in FIG. 7 and a route selection truth table (No. 2) shown in FIG. Output information corresponding to each input information is read from the path selection truth table and output to each selection unit.
[0030]
The route selection truth table shown in FIG. 7 and FIG. 8 selects a transmission channel (Ch1 to ChX) in an empty state based on instruction information indicating that each transmission channel (Ch1 to ChX) is in use (ON). Thus, for example, information indicating transmission data of ACK1 to ACK15 in the enabled state to be selected is selected in each selection unit (BR0_Ch1_SEL to BR0_ChX_SEL, BR1_Ch1_SEL to BR1_ChX_SEL) of the selected empty transmission channels (Ch1 to ChX). Outputs information that is specified in numerical order.
[0031]
The signal of the synchronization detection display channel (AICH) selected and output according to the route selection truth table is the selection unit SEL1 in FIG. ₀ , SEL1 ₁ , ~ SELX ₀ , SELX ₁ Is selected by the selection unit and transmitted from the mobile communication base station apparatus.
[0032]
Next, an embodiment in which the transmission idle time of the synchronization channel (SCH) is effectively used will be described. FIG. 9 shows a configuration of a transmission unit for a synchronous channel (SCH) modulated wave. In the figure, a data storage unit 9-1 stores synchronization channel (SCH) data and DTX data having zero transmission power, and according to the count value of the address counter 9-2, synchronization channel (SCH) data transmission timing. Sometimes the synchronization channel (SCH) data is output, and the DTX data is output to the primary synchronization channel (PSCH) spreading unit 9-4 and the secondary synchronization channel (SSCH) spreading unit 9-5 at times other than the synchronization channel (SCH) data transmission timing. .
[0033]
The code generation unit 9-3 sends a spreading code corresponding to each of the primary synchronization channel (PSCH) spreading unit 9-4 and the secondary synchronization channel (SSCH) spreading unit 9-5 to a timing other than the synchronization channel (SCH) data transmission timing. But it keeps sending without stopping sending.
[0034]
The transmission power control units 9-6 and 9-7 control the transmission power of the primary synchronization channel (PSCH) and the secondary synchronization channel (SSCH), respectively, according to a transmission power instruction from a host device (not shown). At this time, at the timing when DTX data with zero transmission power is output, an instruction to set the transmission power to zero is given, and the transmission power is set to zero according to the instruction.
[0035]
FIG. 10 shows a time chart of transmission of a synchronous channel (SCH) modulated wave. (A) of the figure shows a time chart of data output from the data storage unit 9-1, and (b) of the figure shows a primary or secondary synchronization channel (from the code generation unit 9-3) ( (SSCH) spreading code. (C) of the figure shows a synchronization channel (SCH) modulated wave output from the primary synchronization channel (PSCH) spreading unit 9-4 or the secondary synchronization channel (SSCH) spreading unit 9-5.
[0036]
As shown in FIG. 10, the synchronization channel (SCH) data output from the data storage unit 9-1 is the same as the data of 256 chips (one symbol), and the same data is sent out for each slot. The DTX data with zero transmission power is connected to the (SCH) data, and is input to the spreading unit 9-4 or 9-5 as one data. For DTX data, since the transmission power is zero, a spread signal is not output, and an SCH modulated wave is transmitted from the mobile communication base station apparatus as shown in FIG.
[0037]
FIG. 11 shows a configuration of a diversity channel transmission unit for a synchronous channel (SCH) modulated wave. In this figure, the basic configuration is the same as the configuration shown in FIG. 9, but as the primary synchronization channel (PSCH) spreading unit 9-4, two spreading units 9-4 are used for diversity transmission. ₀ , 9-4 ₁ In addition, as the secondary synchronization channel (SSCH) spreading unit 9-5, two spreading units 9-5 are used for diversity transmission. ₀ , 9-5 ₁ Is provided. And diffusion part 9-4 ₁ And diffusion part 9-5 ₁ Are connected to phase adjusters 11-1 and 11-2, respectively, and the phase adjusters 11-1 and 11-2 perform phase rotation in accordance with the 3GPP standard.
[0038]
FIG. 12 shows a time chart of diversity transmission of a synchronous channel (SCH) modulated wave. The diversity transmission of the synchronous channel (SCH) modulation wave is defined by the 3GPP standard, and as shown in (d) and (e) of FIG. 12, the synchronous channel (SCH) is alternately transmitted between the transmission branches for each slot. ) It is necessary to transmit by “Time Switched Transmit Diversity (TSTD)” that transmits a modulated wave.
[0039]
Therefore, as shown in FIG. 12A, for example, in the first slot Slot1, the transmission branch BR0 transmits data in which the DTX data is linked to the synchronization channel (SCH) data, and the next second slot Slot2. Then, only DTX data is transmitted, and thereafter this operation is repeated.
[0040]
On the other hand, as shown in FIG. 12B, in the transmission branch BR1, as opposed to the transmission branch BR0, only the DTX data is transmitted in the first slot Slot1, and the synchronization channel (SCH) is transmitted in the next second slot Slot2. ) Send data with DTX data connected to data, and repeat this operation.
[0041]
In this way, the transmission branches BR0 and BR1 alternately transmit data in which the DTX data is connected to the synchronization channel (SCH) data and the data of only the DTX data, and switch the time switching transmission diversity (TSTD) alternately for each slot. )I do. Meanwhile, as shown in FIG. 12C, the spreading code can be transmitted continuously.
[0042]
FIG. 13 shows a configuration of a transmission unit that transmits synchronization channel (SCH) data and packet data. The basic principle of this configuration is the same as that shown in FIG. 9, and the data storage unit 13-1 stores synchronization channel (SCH) data, DTX data with zero transmission power, and packet data, and addresses According to the count value of the counter 13-2, the synchronization channel (SCH) data is transmitted at the synchronization channel (SCH) data transmission timing, the DTX data is transmitted at the timing other than the synchronization channel (SCH) data transmission timing, and the synchronization channel (SCH) spreading unit 13- 4 is output to the packet (PKT) spreading unit 13-5 each time packet data is generated.
[0043]
The code generator 13-3 sends the spreading codes corresponding to the synchronization channel (SCH) spreading unit 13-4 and the packet (PKT) spreading unit 13-5 to the synchronization channel (SCH) data transmission timing and packet data transmission timing, respectively. Other than the above, it continues to send without stopping.
[0044]
The spread modulation wave of the synchronization channel (SCH) data output from the synchronization channel (SCH) spreading unit 13-4 and the packet data and spread modulation wave output from the packet (PKT) spreading unit 13-5 are multiplexed by the multiplexing unit 13. After being multiplexed and transmitted by -6, the transmission power control unit 13-7 transmits the spread modulated wave with the transmission power instructed from the host device (not shown). At this time, an instruction to set the transmission power to zero is given at the transmission timing of the DTX data, and the transmission power control unit 13-7 sets the transmission power to zero at the transmission timing of the DTX data.
[0045]
FIG. 14 shows a time chart of transmission of synchronization channel (SCH) data and packet data. (A) of the figure shows a time chart of data outputted from the data storage unit 13-1 and inputted to the synchronization channel (SCH) spreading unit 13-4, and (b) of the figure shows a code generation unit. 13-3 shows a synchronization channel (SCH) spreading code output from 13-3.
[0046]
(C) of the figure shows a time chart of data outputted from the data storage unit 13-1 and inputted to the packet data (PKT) spreading unit 13-5, and (d) of the figure shows a code generation unit. The packet data (PKT) spreading code output from 13-3 is shown. (E) of the same figure shows the modulated wave output from the multiplexing part 13-6.
[0047]
As shown in FIG. 14, the synchronization channel (SCH) data output from the data storage unit 13-1 is transmitted as the same data for only one symbol for each slot as one symbol data, and the synchronization channel (SCH) data Are connected to zero transmission power DTX data and input as one data to the synchronization channel (SCH) spreading section 13-4.
[0048]
In the synchronization channel (SCH) spreading unit 13-4, no transmission signal is output for DTX data because the transmission power is zero. Packet data is transmitted between transmissions of a synchronous channel (SCH) modulated wave. It should be noted that the packet data spreading code is continuously sent out continuously as shown in FIG. 4D by connecting DTX data with zero transmission power at the timing of non-transmission of packet data in each slot. be able to. From the multiplexing unit 13-6, as shown in FIG. 14E, packet data is transmitted between them along with the synchronization channel (SCH) modulated wave, and the synchronization channel (SCH) can be used effectively.
[0049]
FIG. 15 shows the configuration of the diversity transmitter of the primary and secondary synchronization channels. The basic principle of this configuration is the same as that shown in FIG. At the time of diversity transmission of the synchronization channel (SCH), the primary synchronization channel (PSCH) data read from the data storage unit 15-1 is used as the branching units 15-3 and 15- of the branch BR0 and the branch BR1 of the first channel (Ch1). 4 and the secondary synchronization channel (SSCH) data read from the data storage unit 15-1 is sent to the branch units BR0 and BR-6 of the branch BR1 of the second channel (Ch2). .
[0050]
At the time of diversity transmission, the primary synchronization channel (PSCH) spreading code output from the code generation unit 15-7 is selected for the branch BR0 of the first channel (Ch1) and the spreading units 15-3 and 15-4 of the branch BR1. The secondary synchronization channel output from the code generation unit 15-7 is added to the branch BR0 of the second channel (Ch2) and the spreading units 15-5 and 15-6 of the branch BR1. Add (SSCH) spreading code.
[0051]
Accordingly, the spread modulated wave of the primary synchronization channel (PSCH) is output from the branch BR0 and the branch BR1 of the first channel (Ch1), and the spread of the secondary synchronization channel (SSCH) from the branch BR0 and the branch BR1 of the second channel (Ch2). A modulated wave is output, and a spread modulated wave having the transmission power instructed by the transmission power control units 15-7 to 15-10 is transmitted.
[0052]
When the phase adjustment units 15-11 and 15-12 do not perform diversity transmission according to the diversity (Div) control signal, the phase adjustment units 15-11 and 15-12 transmit the input signal at a fixed phase and perform diversity transmission without performing phase rotation. Performs phase rotation according to the 3GPP standard only on the signal on the transmission branch (BR1) side.
[0053]
When diversity is not transmitted, the primary synchronization channel (PSCH) data read from the data storage unit 15-1 is sent to the spreading unit 15-3 of the branch BR0 of the first channel (Ch1), and the data storage unit 15-1 The secondary synchronization channel (SSCH) data read from is sent to the spreading unit 15-4 of the branch BR1 of the first channel (Ch1).
[0054]
When diversity is not transmitted, the primary synchronization channel (PSCH) spreading code output from the code generation unit 15-7 is added to the spreading unit 15-3 of the branch BR0 of the first channel (Ch1). The secondary synchronization channel (SSCH) spreading code output from the code generation unit 15-7 is selected by the selection unit 15-8 and added to the spreading unit 15-4 of the branch BR1 of the channel (Ch1).
[0055]
As described above, in the mobile communication base station apparatus having the diversity transmission function, when the diversity transmission is not performed, the primary synchronization channel (PSCH) and the secondary synchronization channel (SSCH) modulated waves are used by the diversity transmission unit for one channel. The diversity transmission unit for another channel can be used for the other two data transmissions, and the channel can be used effectively.
[0056]
【The invention's effect】
As described above, according to the present invention, the mobile communication base station apparatus having the diversity transmission function includes means for using the diversity transmission unit for data transmission of other channels when the diversity transmission is not performed. Thus, the number of channels per device can be increased, and the number of installed mobile communication base station devices can be reduced. Also, since the number of channels to be accommodated is small, the number of modulation units in the mobile communication base station apparatus can be reduced, and the cost can be reduced.
[0057]
In addition, by selecting a transmission channel that is not in use and transmitting the synchronization detection display information through the transmission channel, there is no need to always allocate 16 synchronization detection display channels (AICH), and the mobile communication base It is possible to make room for channel resources in the station apparatus.
[0058]
Also, instead of stopping spreading code output when spreading modulation waves are not sent, transmission data is connected to data with zero transmission power, and transmission of spreading modulation waves is stopped by multiplying the spreading code with data with zero transmission power. By doing so, channel control can be facilitated.
[0059]
In addition, by sending a plurality of packet data to an empty area after the synchronization channel (SCH) data or a slot not transmitting the synchronization channel data at the time of transmission of the synchronization channel data by time switching transmission diversity (TSTD), However, it is possible to reduce the number of unused channels that do not transmit data, and to improve channel efficiency.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an embodiment of the present invention that effectively uses a diversity transmitter.
FIG. 2 is a diagram illustrating a configuration of a branch selection unit according to the present invention.
FIG. 3 is a diagram illustrating a configuration of a spreading code generation unit according to the present invention.
FIG. 4 is a diagram illustrating an embodiment of the present invention that effectively uses a synchronization detection display channel (AICH).
FIG. 5 is a diagram showing a configuration of an AICH processing unit of the present invention.
FIG. 6 is a diagram showing a configuration of a channel selection unit of the present invention.
FIG. 7 is a diagram showing a route selection truth table (part 1) according to the present invention.
FIG. 8 is a diagram showing a route selection truth table (No. 2) according to the present invention.
FIG. 9 is a diagram illustrating a synchronization channel (SCH) modulated wave transmission unit according to the present invention.
FIG. 10 is a diagram showing a transmission time chart of a synchronous channel (SCH) modulated wave according to the present invention.
FIG. 11 is a diagram illustrating a synchronization channel (SCH) modulation wave diversity transmission unit according to the present invention;
FIG. 12 is a diagram showing a diversity transmission time chart of a synchronous channel (SCH) modulated wave according to the present invention.
FIG. 13 is a diagram illustrating a transmission unit that transmits synchronization channel (SCH) data and packet data according to the present invention.
FIG. 14 is a diagram showing a transmission time chart of synchronization channel (SCH) data and packet data according to the present invention.
FIG. 15 is a diagram illustrating a diversity transmitter of primary and secondary synchronization channels.
[Explanation of symbols]
1-1 Data storage
1-2 Branch selector
1-3 _Ten ~ 1-3 _X1 Diffusion part
1-5 ₁ , 1-5 _X Phase adjuster
1-6 Spreading code generator

Claims (4)

In a mobile communication base station apparatus of a spread spectrum modulation system cellular communication system having a diversity transmission function in each transmission channel,
A transmission branch selection means for switching a plurality of transmission data between when the diversity transmission is performed and when the diversity transmission is not performed, and distributing the transmission data to a spread modulation unit corresponding to each transmission branch of each transmission channel;
A spreading code generation unit that outputs different spreading codes corresponding to transmission data when the diversity transmission is performed and when not performed with respect to the spreading modulation unit corresponding to the transmission branch;
Means for spreading and modulating the synchronization detection display channel in units of transmission branches of each transmission channel;
Channel selection means for selecting a transmission channel that is not in use and assigning the synchronization detection display channel modulated wave to the transmission channel;
A mobile communication base station apparatus comprising: In a mobile communication base station apparatus of a spread spectrum modulation system cellular communication system having a diversity transmission function in each transmission channel,
A transmission branch selection means for switching a plurality of transmission data between when the diversity transmission is performed and when the diversity transmission is not performed, and distributing the transmission data to a spread modulation unit corresponding to each transmission branch of each transmission channel;
A spreading code generation unit that outputs different spreading codes corresponding to transmission data when the diversity transmission is performed and when not performed with respect to the spreading modulation unit corresponding to the transmission branch;
In a configuration for generating a synchronization channel modulated wave, means for transmitting data with zero transmission power to a free area after the synchronization channel data to be transmitted;
Means for performing spreading modulation on the synchronization channel data and the subsequent data with zero transmission power by a spreading code for each transmission branch of each transmission channel ;
Spreading code generation means for continuously transmitting the transmission of the spreading code without stopping the transmission even during the transmission period of the transmission power zero data;
Channel selection means for selecting a transmission channel that is not in use and assigning the modulated wave of the synchronization channel data and subsequent data with zero transmission power to the transmission channel;
A mobile communication base station apparatus comprising: In the configuration of the transmission unit of the synchronization channel data by the time switching transmission diversity for transmitting the synchronization channel data from different transmission branches alternately for each slot,
Means for transmitting data having zero transmission power to a slot next to a slot for transmitting synchronization channel data;
Means for performing spreading modulation with a spreading code on a slot for transmitting the synchronization channel data and a slot for data having zero transmission power subsequent thereto;
Spreading code generation means for continuously transmitting the transmission of the spreading code without stopping the transmission even during the transmission period of the transmission power zero data;
The mobile communication base station apparatus according to claim 2 , further comprising: Means for sending a plurality of packet data to the free space after the synchronization channel data and data with zero transmission power to the free space thereafter;
Means for transmitting a plurality of packet data and data having zero transmission power to a free space thereafter in a slot not transmitting synchronization channel data when transmitting synchronization channel data by time switching transmission diversity;
Means for performing spreading modulation on the packet data and subsequent data with zero transmission power using a spreading code;
Spreading code generation means for continuously sending out the spreading code without stopping the sending of the spreading code even during the transmission period of the data with zero transmission power;
The mobile communication base station apparatus according to claim 2 or 3 , further comprising:

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