JP2009171105A - Wireless base station device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless base station device capable of giving an IP function of a private call system as alternatives. <P>SOLUTION: Voice data of ADPCM (Adaptive Differential Pulse-Code Modulation) coding received by a wireless part 6 are converted into a PCM (Pulse-Code Modulation) code by a code conversion part 7, read to a bas line, are transferred to an ADSL interface part 3 in the case of an ADSL line connection, or are transferred to an LAN interface part 4 in the case of an LAN line connection. Moreover, voice data of PCM code transmitted by the ADSL line or the LAN line are converted into the ADPCM code by the code conversion part 7 and sent to an antenna via the wireless part 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a radio relay system, and more particularly to a radio base station apparatus suitable for IP telephone connection.

  A simple mobile phone system (PHS; Personal Handyphoe System) has been expanded especially as a local communication system (control device (CTE), base station device (BS), mobile station device (PS)) for offices.

  This conventional system has a function of connecting to an external telephone charged as a subscriber line.

  On the other hand, in recent years, an IP (Internet Protocol) telephone system, which does not charge for a call each time, has come to be used for reasons of cost saving.

  In the private communication system using the PHS method, in addition to the conventional method, there is an increasing demand for options for IP telephones.

  FIG. 3 is a block diagram of a BS (PHS radio base station) 21 as a base station apparatus of a private communication system for offices using the prior art and will be schematically described.

  The BS 21 includes a power source unit 1, a ping-pong transmission unit 2, a control unit 50, a radio unit 6, a two-wire metallic cable connection unit (RJ-11) 80, and the like.

  The two-wire metallic cable connection unit 80 is a modular connector (RJ-11; usually two-wire) connected to an external general telephone line.

  One end of the ping-pong transmission unit (PP) 2 is connected to the line-side RJ-11. The other end of the P processing function circuit is a ping-pong transmission processing circuit (PP; ping-pong transmission system) connected to the control unit 50 (BASE-Band).

  The control unit 50 includes an MPU-CORE circuit having a CPU function, a MODEM circuit connected to the MPU-CORE circuit, which performs baseband signal processing on a signal from the ping-pong transmission unit 2 by a BASE-Band circuit and performs modulation / demodulation for PHS radio. And controls transmission / reception of audio data.

  The radio unit 6 is a radio amplifier circuit that is connected to the control unit 50 (MODEM circuit) and configures a line with a wireless PHS terminal (PS; mobile station apparatus) via an antenna.

  The power supply unit 1 is a voltage conversion circuit that extracts a DC voltage from the telephone line (two-wire metallic cable) and supplies it as a necessary voltage to an internal circuit.

  Now, when IP telephones are used, such a conventional system (existing system equipment) is diverted as much as possible, and further, existing diversion cables are diverted, and a new system expansion (control apparatus, base station apparatus) that can make IP telephones. In particular, there has been a demand for a base station apparatus that has various line connection methods and that can be easily made into an IP.

As a prior art of the present invention, a device (such as a measurement device) having a serial interface such as RS-232C is wirelessly controlled by a PC having a LAN interface, and therefore via a modem using the PHS method. There is a proposal to connect to a LAN line. (For example, see Patent Document 1)
Japanese Patent Laying-Open No. 2005-184053 (FIG. 1)

  3 does not have an IP phone (VoIP; Voice over Internet Protocol; technology for sending and receiving voice data using a network such as the Internet), and therefore has a high running cost when connecting to an outside line. .

  Furthermore, when a device such as a BS is relocated, or when a BS is newly installed or added, wiring work for laying a new dedicated cable is required, which increases the construction cost.

  In addition to diverting the conventional laying cable and signal line feeding method, the conventional technology P.I. A BS that can perform P transmission connection, generalized LAN line connection and ADSL line connection, and can be given options to adapt it to the user's system situation, and can reduce the construction costs such as wiring. There was no.

  An object of the present invention is to provide a radio base station apparatus that solves the above-described problems of the prior art and is provided with an IP function of a local call system as an option.

In order to achieve this object, a radio base station apparatus of the present invention includes a radio unit, a control unit, a code conversion unit, a LAN interface unit, an ADSL interface unit, and a ping-pong transmission unit, and a ping-pong transmission line , A wireless base station apparatus that selectively connects to a LAN line or an ADSL line and relays,
When the code conversion unit is connected to the LAN line or the ADSL line, the voice data of the ADPCM code received by the wireless unit is converted into a PCM code and output, and the ADSL interface unit or the LAN PCM code voice data transferred from the interface unit is converted to ADPCM code and output,
When connected to the LAN line, the LAN interface unit converts the PCM code from the code conversion unit into a packet code configuration, further converts it into an Ethernet (registered trademark) frame, and sends it to the LAN line ,
When the ADSL interface unit is connected to the ADSL line, the PCM code from the code conversion unit is converted into a packet code configuration, further converted into an ATM frame, and sent to the ADSL line,
The ping-pong transmission unit is configured to send an ADPCM code to the ping-pong transmission line when connected to the ping-pong transmission line.

  Further, when connected to a LAN line, the Ethernet (registered trademark) frame received via the LAN interface unit is converted from a PCM code to an ADPCM code, and transmitted from the wireless unit to the PHS terminal; and When connected to the ADSL line, the ATM frame received via the ADSL interface is converted from the PCM code to the ADPCM code and transmitted from the radio unit to the PHS terminal.

  According to the present invention, the IP of the local call system (system having a VoIP function) is achieved, and the communication cost when using the outside line is reduced.

  In addition, since a generalized LAN cable is used by using the LAN interface, wiring work for a conventional dedicated cable is not required at the time of relocation and expansion.

  In new installations, the scale of the line work can be reduced by laying the basic LAN cable.

  By having an ADSL interface, IP can be achieved while diverting existing cables.

  Even after the transition from the conventional system to the IP system, it is possible to operate as a PHS base station (BS) having the conventional function.

  Also in the BS (IP-BS device) of the present invention, it is possible to supply power from a communication line, so there is no need to newly install an external AC power source.

  FIG. 2 shows a system configuration diagram of a radio base station apparatus according to an embodiment of the present invention and will be described.

  The system configuration of the present invention includes a control device 30 (CTE), a BS device 21 (PHS radio base station), at least one IP-BS device 20 (IP-compatible local PHS base station) as a local PHS radio system, It comprises a plurality of PHS terminals 40 (PS).

  The control device 30 (CTE) is connected to the BS device 21, and the BS P.P. A HUB is connected to the BSIF board that performs P transmission control, the ADSLIF board that is connected to the IP-BS apparatus 20 and performs ADSL line control of the IP-BS apparatus, and the IP-BS apparatus 20 and the external (upper) LAN line as necessary. And a LANIF board that controls a plurality of LAN lines, and an MCP board that performs integrated control of these board circuits and system control including control of external network LAN lines.

  When connecting a plurality of LAN lines, if necessary, a hub (HUB) having a plurality of ports may be used as a LAN repeater and the LAN lines may be cascade-connected.

  The control device 30 (BSIF) and the BS 21, and the control device 30 (ADSLIF) and the IP-BS device 20 (C) are each connected by a dedicated two-wire cable.

  Since the control device 30 (LANIF) and the IP-BS device 20 (A, B) are LAN connection type IP-BS devices, they are connected by a general-purpose LAN cable.

  BS21 (PHS radio base station) is a conventional base station function such as a ping-pong transmission processing circuit (PP), baseband signal processing, and radio amplification.

  The IP-BS20 devices (A), 20 (B), and 20 (C) (IP-compatible local PHS base stations) have three types of connection forms having the configuration of the embodiment of the present invention described in detail below. A radio base station apparatus having a PHS base station function. The IP-BS devices 20 (A), 20 (B), and 20 (C) have the same configuration, and are hereinafter referred to as the IP-BS device 20 except for individual display.

  PS 40 (A, B, C, M, N, P) is a mobile station of the PHS system that is connected to the BS 21 and the IP-BS device 20 via a radio line.

  As an embodiment of the present invention, the circuit configuration of the IP-BS device 20 is shown in FIG.

  The IP-BS device 20 includes a power supply unit 1 (A), 1 (B), a ping-pong transmission unit 2, an ADSL interface unit 3, a LAN interface unit 4, a control unit 5, a radio unit 6, a code conversion unit 7, and a two-wire system. It is composed of a metallic cable connection unit 8, a line changeover switch 9, a LAN connection unit 10, and a storage element (RAM, Flash Memory).

  The power supply unit 1 includes power supply units 1 (A) and 1 (B). The power supply unit 1 (A) supplies the DC voltage superimposed on the two-wire metallic cable to the DC / DC converter via the two-wire metallic cable connection unit 8, and the operating voltage ( In order to obtain Vcc, etc., the voltage is stepped down or boosted and supplied to each part. On the other hand, the power supply unit 1 (B) uses a LAN cable PoE (Power over Ethernet (registered trademark); a technology for supplying power using an Ethernet connection cable) to convert a DC voltage from a line into a DC / DC converter. In order to obtain an operating voltage (Vcc or the like) necessary for the circuit block of each part, the voltage is stepped down or boosted and supplied to each part. The power supply unit 1 (A) or (B) is operated by any connected line.

  Since the outputs of the DC / DC converters of the power supply units 1 (A) and (B) are supplied to each circuit through a backflow prevention diode, a local power supply type (AC power supply not shown) Part) is also possible.

  The ping-pong transmission unit 2 is a conventional telephone line transmission technology based on a ping-pong transmission system (Ping-Pong transmission system (PP); pulse bidirectional transmission in a one-pair (two-core) metallic telephone line). Connect to line switch 9 The other end of the P processing function circuit is a ping-pong transmission processing circuit connected to the control unit 5 (BASE-Band).

  The ADSL interface unit 3 is connected to the line changeover switch 9 on the line side, is an ADSL (Asymmetric Digital Subscriber Line; ADSL recommendation G992.1, ADSL-lite recommendation G992.2 standard), and a two-core copper wire (metallic) This is a MODEM function circuit of a communication system that enables high-speed data communication using a subscriber telephone line.

  The ADSL MODEM function circuit has processing functions for ATM (Asynchronous Transfer Mode) and PPP line connection procedure (Point to Point Protocol; a protocol often used for dial-up connection to connect a computer to a network through a telephone line). .

  The circuit is realized as an ADSL MODEM IC having AFE (Analog Front End; analog front end), DMT (Discrete Multi Tone; a method of re-dividing a used band and QAM modulating each frequency) and an ATM processing function. The input / output of the ADSL-processed audio data of the ADSL interface unit 3 is connected to the MPU bus line, and this audio data is transferred to the bus line to which data input / output is transferred under the control of the control unit 5 (MPU-CORE). Can be placed.

  The LAN interface unit 4 includes functional circuits of a LANC (LAN Controller) circuit and a PHY (Physical Layer; physical protocol for network protocol; Ethernet (registered trademark) frame; IEEE 802.3 LAN standard compliant transmission protocol) circuit. One of the LANCs is connected to the internal bus line of the control unit 5 (MPU-CORE circuit), the other is connected to the PHY, the PHY is on the external line side, and the LAN connection unit via the line transformer. 10 and a circuit configuration connected to the power supply unit 1 (B).

  It is a processing circuit that performs LAN interface control by the operation of these circuits. The audio data is loaded on the internal bus line of the MPU-CORE circuit.

  The control unit 5 is connected to the MPU-CORE circuit, which is a central processing unit of the IP-BS device 20, the MODEM circuit that performs wireless modulation / demodulation, and the MPU-CORE, and performs baseband signal processing. A BASE-Band circuit is provided, and MPU-CORE is connected to internal and external bus lines.

  The functional circuit of the control unit 5 may be realized as a one-chip IC including a LANC circuit and a PHY circuit included in the LAN interface unit 4.

  The MPU-CORE function of the control unit 5 includes data transfer processing with the ADSL interface unit 3, data transfer processing with the LAN interface unit 4, and code conversion unit 7 (via the external or internal bus line). DPRAM) data transmission / reception is controlled. Further, a BASE-Band circuit that performs baseband signal processing is controlled by individual connection with the MPU-CORE, and MODEM control is performed for exchanging signals with the wireless unit 6. In addition, in order to achieve the VoIP function, control processing for code conversion is performed on audio data with the radio interface circuit (MODEM).

  To the bus line under MPU-CORE management, a flash memory (Flash Memory) as a storage memory for programs and a RAM as a temporary storage memory for data and the like are connected.

  One of the radio units 6 is connected to the control unit 5 (MODEM circuit) and the other is connected to the antenna, and the radio unit 6 is configured to be connected to the PHS terminal 40 (PS) by radio via the antenna. It has functions such as modulation / demodulation, frequency conversion, and amplification.

  The code conversion unit 7 includes a DPRAM (Dual Port RAM) connected to the bus line, a CPLD S / P (Parallel Serial Conversion Circuit based on Complex Programmable Logic Device) connected to the DPRAM, and one connected to the CPLD S / P. The other is connected to the control unit 5 (BASE-Band) ADPCM / PCM (ADPCM; Adaptive Differential Pulse Code Modulation; speech coding method used in the PHS system; PCM; Pulse Code Modulation; analog signal sampling; The function IC of the used pulse code modulation system is the central part of the present invention.

  Here, the speech encoding method used in the PHS system is an ADPCM code (4 bit configuration), while the speech encoding method used in the VoIP system is a PCM code (8 bit configuration). The unit 7 (ADPCM / PCM) performs code conversion between both code systems having different code systems.

  The two-wire metallic cable connecting portion 8 includes a terminal block (three terminals) connected to an external ADSL line and an external P.D. A modular connector (RJ-11; a 6-pole modular connector used for a general telephone line (usually 2-wire type)) connected to the P transmission line is provided.

  Further, in the internal circuit, it is connected to the line changeover switch 9 through a capacitor for blocking direct current, and is connected to the power supply unit 1 (A) through a coil for blocking alternating current.

  A surge absorber element for lightning protection is connected between each two-wire line and the ground.

  On the other hand, when the IP-BS device 20 is connected to the ADSL line, the line changeover switch 9 connects the circuit of the two-wire metallic cable connection unit 8 (terminal block) to the ADSL interface unit 3 on the other hand. The apparatus 20 is a P.D. When connected to the P transmission line, the circuit is switched so that the circuit of the two-wire metallic cable connection unit 8 (RJ-11) is connected to the ping-pong transmission unit 2.

  The LAN connection unit 10 is provided with an RJ-45 (Ethernet (registered trademark); 8-pole modular connector used for connecting an Ethernet (registered trademark) or ISDN line) for connection to an external LAN line, and there is an internal connection. Are connected to the LAN interface section 4 and the power supply section 1 (B).

  The ping-pong transmission unit 2 connects the line side to the RJ-11 via the line change-over switch 9. This is a conventional ping-pong transmission processing circuit in which the other end of the P processing function circuit is connected to the control unit 5 (BASE-Band circuit).

  Next, a signal flow in the code conversion unit 7 at the time of communication with the PS 40 will be described.

  ADPCM code, which is audio data reproduced from the radio unit 6 (reception mode) through the control unit 5 (MODEM, BASE-Band), is converted to PCM code by ADPCM / PCM, and serial code is parallelized by CPLD S / P. Further, the parallel code is stored and stored in a memory area at a predetermined position of the DPRAM.

  The audio data of the PCM code stored in the DPRAM is read to the bus line under the control of the control unit 5 (MPU-CORE), and if it is connected to the ADSL line, it is transferred to the ADSL interface unit 3 and the LAN line If it is a connection, it is transferred to the LAN interface unit 4.

  On the other hand, the voice data (PCM code) transmitted through the ADSL line or the LAN line is subjected to the respective line protocol processing in the ADSL interface unit 3 or the LAN interface unit 4, and is taken in as a voice data string of the PCM code. The data is read out on the bus line under the control of the control unit 5 (MPU-CORE) and further stored in a memory area at a predetermined position of the DPRAM.

  The PCM code stored in the memory area of the DPRAM at a predetermined position is converted from parallel to serial, converted to ADPCM code by ADPCM / PCM, and transmitted through the control unit 5 (BASE-Band, MODEM) to the radio unit 6 (transmission mode). A signal is transferred as voice data of ADPCM code.

  By providing the configuration of the above embodiment, the PHS radio base station having the PHS radio interface becomes a device having a LAN interface and an ADSL interface having a VoIP function in addition to the conventional system ping-pong transmission interface.

  According to the present invention, since it has a function of mutual conversion between ADPCM code and PCM code, it is possible to connect ADPCM encoded voice transmitted and received by PS (cordless cordless handset) and PCM encoded voice transmitted and received by IP telephone. It is possible to provide a radio base station apparatus configured as a local PHS base station (IP-BS) apparatus capable of performing relaying.

  The present invention is applied to a radio communication system used for mobile communication, and can be used as a communication network in a business office as an example.

It is a block diagram of the IP-BS apparatus (IP corresponding local PHS base station) of the present invention. It is a system configuration | structure figure of IP corresponding local PHS of this invention. It is a block diagram of BS (PHS radio base station) of the prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 (A), 1 (B) Power supply part 2 Ping-pong transmission part 3 ADSL interface part 4 LAN interface part 5 Control part 6 Radio | wireless part 7 Code conversion part 8 2-wire type metallic cable connection part 9 Line switch 10 LAN connection part 20 , 20 (A), 20 (B), 20 (C) IP-BS device (IP-compatible local PHS base station)
21 BS (PHS radio base station)
30 Controller (CTE)
40 PHS terminal (PS)

Claims (1)

A radio base station that includes a radio unit, a control unit, a code conversion unit, a LAN interface unit, an ADSL interface unit, and a ping-pong transmission unit, selectively connects to a ping-pong transmission line, a LAN line or an ADSL line, and relays A device,
The code converter is
When connected to the LAN line or the ADSL line, the voice data of the ADPCM code received by the wireless unit is converted into a PCM code and output,
The PCM code voice data transferred from the ADSL interface unit or the LAN interface unit is converted into an ADPCM code and output.
The LAN interface unit
When connected to the LAN line, the PCM code from the code converter is converted into a packet code structure, further converted into an Ethernet (registered trademark) frame, and sent to the LAN line.
The ADSL interface unit is
When connected to the ADSL line, the PCM code from the code converter is converted into a packet code structure, further converted into an ATM frame, and sent to the ADSL line.
The ping-pong transmission unit is
A radio base station apparatus configured to send an ADPCM code to the ping-pong transmission line when connected to the ping-pong transmission line.

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