KR100461071B1 - Wireless LAN Access-Point Composite Device - Google Patents

Abstract

PURPOSE: A wireless LAN access point composite device is provided to shorten a software development period and achieve improved performance of a system, by separating a wireless LAN module and a system module. CONSTITUTION: A wireless LAN access point composite device comprises a wireless LAN module, a system module(195), and a connecting member(160). The wireless LAN module includes RF communication modules(120 to 155), a network processor(110), a memory module(115), and internal connectors. The system modules includes an Ethernet PHY(170), a system processor(180), a main system(190), and one or more external connectors. The network processor provides an external wireless LAN communication by performing a wireless LAN media connection control and a wireless LAN baseband processing for the RF communication module, provides a wire LAN communication by performing a wire LAN media connection control for an external Ethernet PHY through a second MII-IF port, provides a connection to the wireless LAN communication and the wire LAN communication for a main system through a first MII-IF port, and provides a relay service between the wireless LAN communication and the wire LAN communication. The memory module stores execution program codes of the network processor, and provides a memory space required for operation of the execution program. The internal connectors connect an external wireless LAN antenna for providing RF media connection performed by the RF communication module.

Description

Wireless LAN AP Composite Device {Wireless LAN Access-Point Composite Device}

The present invention is to separate the system module and the wireless LAN module, and to connect the network processor of the wireless LAN module and the system processor of the system module to the first MII interface to configure the wireless LAN connection and remove the network processor and Ethernet PHY of the wireless LAN module The present invention relates to a WLAN AP composite apparatus configured to connect to a MII interface to configure a wired LAN connection to perform an access point operation, but to set a first MII interface to a PHY mode and a second MII interface to a MAC mode in a network processor.

Conventionally, wireless LAN terminals and wireless LAN access devices have been widely used in notebook computers, and recently, wireless LAN modules are mounted on home appliances or external storage devices such as digital STBs or DVD players, etc. Attempts have been made to use it. In order to install and operate the wireless LAN module, the MII interface provided in the system processor is connected to the Ethernet PHY for the wired LAN connection, and the wireless LAN module is normally connected through the PCMCIA connector to be recognized and initialized by the system processor. It was common to be configured to handle LAN interrupts.

However, in the case of configuring the WLAN device as described above, an interface such as PCMCIA must be separately prepared, and the hardware configuration becomes complicated, and since the system processor must integrate and process the control program for the WLAN module, the software development becomes complicated. It takes a long time, and the system processor must process the WLAN interrupt for the relay operation, so that as the network transaction increases, the overall system performance decreases.

Therefore, in the present invention, after separating the system module and the WLAN module, the WLAN processor is configured by connecting the network processor of the WLAN module and the system processor of the system module to the first MII interface to configure the WLAN connection and the network processor of the WLAN module and the Ethernet PHY. To establish a wired LAN connection by connecting to a second MII interface to perform an access point operation, but in a network processor, the first MII interface is set to PHY mode and the second MII interface is set to MAC mode to operate the software. The purpose of the present invention is to provide a WLAN AP composite device which can shorten and improve the overall system performance and can implement the WLAN AP composite device in a compact form as a simple hardware configuration.

1 is a view showing the internal configuration of a wireless LAN AP composite device according to an embodiment of the present invention.

2 is a view showing a PCB configuration of a wireless LAN module according to an embodiment of the present invention.

3 is a diagram illustrating a configuration of a MII interface signal connection according to an embodiment of the present invention.

Figure 4 is a diagram showing the internal configuration of a WLAN AP composite device according to another embodiment of the present invention.

5 is a diagram illustrating a configuration for connecting an antenna in a WLAN AP composite device according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: wireless LAN module 110: network processor

115: memory 120: WLAN RF transceiver

160: Connector 170: Ethernet PHY

180: system processor 190: main system

195: system module

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a view showing the internal configuration of a wireless LAN AP composite device according to an embodiment of the present invention, the wireless LAN AP composite device of the present invention is a main system 190 such as a digital STB or DVD player, an external storage device, etc. It consists of a system module (195) for providing a wireless LAN module 100 for providing a WLAN network function, both modules (100, 195) is a specific such as a mini PCI connector or a dip (DIP) connector, etc. It is coupled to each other through the connector mechanism 160 of the. In the present invention, the system processor 180 for controlling the system module 195 and the network processor 110 for controlling the wireless LAN module 100 are functionally independent of each other, except that the system module 195 is connected to the wired / wireless LAN network. It is connected to the MII interface to provide a service.

The memory 115 of the WLAN module 100 stores the execution program code of the network processor 110. The network processor 110 controls the wired / wireless LAN connection operation with an external medium according to the execution program code. Provide relay service. First, in order to control a wired / wireless LAN access operation with an external medium, the network processor 110 performs a wired / wireless LAN media access control (MAC) and a wireless LAN baseband processing (BBP) as specified in a corresponding standard, and performs a wired / wireless LAN relay service. In order to provide the network processor 110 performs a relay process between the wired LAN data and wireless LAN data. On the other hand, the memory 115 provides a space for temporarily storing data when the network processor 110 performs an operation.

The network processor 110 has two MII interfaces, that is, 'MII_0' and 'MII_1' for connection with an external IC. In the present invention, the MII_0 operates in a MAC mode and the MII_1 operates in a PHY mode. As shown, the MII_0 interface of the network processor 110 is connected to the Ethernet PHY 170 of the system module 195 through the connector 160. Since the MII_0 operates in the MAC mode, the Ethernet PHY 170 is in the PHY mode. MII interface. The network processor 110 is connected to the Ethernet PHY 170 through the MII_0 interface, and the network processor 110 performs wired LAN media access control for a wired LAN connection.

As shown, the MII_1 interface of the network processor 110 is connected to the system processor 180 of the system module 195 through the connector 160. Since the MII_1 operates in the PHY mode, the system processor 180 is a MAC. A mode MII interface is provided, whereby the system processor 180 of the system module 195 receives a wired LAN and / or a WLAN network service from the WLAN module 100. Depending on the system implementation, the system processor 180 may be provided with only one of the wired LAN service and the wireless LAN service, or both. As shown, the network processor 110 and the system processor 180 may further include a specific control interface and a serial communication interface, for example, a JTECK port, a system reset port, or an RS-232C serial communication interface. Do.

In the WLAN AP composite apparatus of the present invention, the Ethernet PHY 170 and the RJ-45 port (not shown) may be mounted to the WLAN module 100 or the system module 195, as shown in FIG. 1. In this case, it is possible to additionally obtain the effect of improving the development efficiency and component utility of the system. That is, when the wireless LAN module 100 is coupled through the connector 160, the system operation is performed as described above, and when the wireless LAN module 100 is not coupled, the MAC of the system processor 180 is combined. The mode MII interface and the PHY mode MII interface of the Ethernet PHY 170 may be directly connected to provide a wired LAN connection to the system module 195. As a result, all functions of the wireless LAN module 100 and the system module 195 can be independently tested, thereby improving the development efficiency. Also, the models and mounting of the wireless LAN module 100 are installed for each product model. Unused models can share the same PCB, which can improve the efficiency of the parts.

Meanwhile, in the WLAN module 100, a module performing high frequency (RF) communication with an external medium, that is, the RF transceiver 120, the power amplifiers 130 and 135, the low noise amplifiers 125 and 140, and the duplexer 145. The configuration of the switch 150 and the antenna 155 is well known in the wireless LAN field, and is not limited to that shown in FIG. 1. For example, the RF transceiver 120 may be configured as a single DSP to selectively support IEEE 802.11bg and IEEE 802.11a, or configured as two DSPs to simultaneously support IEEE 802.11bg and IEEE 802.11a. It should be construed that it is possible within the scope of the present invention. In addition, the RF communication module 120 to 155 may be configured in various ways in the internal connection.

FIG. 2 is a diagram illustrating a PCB configuration of a WLAN module 100 according to an embodiment of the present invention. In particular, FIG. 2 illustrates an embodiment in which the connector mechanism 160 is configured according to hardware specifications of a mini PCI interface. In the mini PCI specification, the interface consists of a total of 124 pins, each having 62 pins on both sides. In the illustrated embodiment, hardware specifications such as connector shape and pin arrangement are implemented according to the mini PCI specification. If present). That is, as shown in FIG. 2, all 124 pins are allocated to the MII_0 interface 210, the MII_1 interface 220, and the CTRL interface 230. On the other hand, the WLAN module 100 should also be provided with an antenna terminal 240 for connecting the WLAN antenna, Figure 2 shows an embodiment thereof.

3 is a diagram illustrating a configuration of an MII interface signal connection according to an embodiment of the present invention. As described above with reference to FIG. 1, the network processor 110 includes two MII interfaces, but MII_0 is in MAC mode. It is configured and operates, and MII_1 is set and operated in PHY mode. The MII_0 interface of the network processor 110 is connected to the PHY mode MII interface of the Ethernet PHY 170 in MAC mode, whereby the network processor 110 connects to the Ethernet PHY 170, transformer 310, and RJ-45 port 320. ) To access the wired LAN connection.

In addition, the MII_1 interface of the network processor 110 is connected to the MAC mode MII interface of the system processor 180 as a PHY mode, through which the system processor 180 may receive a WLAN and / or a wired LAN access service. The system processor 180 may extend the function and utility of the main system 190 through a wireless LAN and / or a wired LAN connection. For example, in the case of a digital STB or a DVD player, AV data may be transmitted or received through a wired or wireless LAN network. For example, in the case of an external storage device, various devices connected to a wired / wireless LAN network may be configured to share an internal memory space.

FIG. 4 is a diagram illustrating an internal configuration of a WLAN AP composite device according to another embodiment of the present invention. Compared to the embodiment of FIG. 1, the internal connection of the RF communication modules 420 to 455 is different, and Ethernet PHY ( 470 may be disposed in the WLAN module 400. First, the RF communication modules 420 to 455 will be described. The configuration for performing RF communication in the WLAN module 400 is variously modified as long as the basic function of providing an RF communication connection for the WLAN service is maintained. 1 and 4 are shown differently from each other to show this. Next, the Ethernet PHY 470 will be described. In this embodiment, the Ethernet PHY 470 is disposed in the WLAN module 400, which is the Ethernet PHY 470 and the RJ in the WLAN AP composite device of the present invention. The arrangement of the -45 port 475, and thus the configuration of the connector mechanism 460, is intended to represent the fact that it can be designed in various ways depending on the implementation.

4 illustrates an external storage system that includes an HDD medium 465 as the main system 190, wherein the external storage device 495 shown accesses the HDD medium 465, i.e., reads / writes data. The operation may be implemented to enable both the first route of the wired / wireless LAN network connection through the system processor 480 and the second route of the USB direct connection through the USB controller 490. As a result, the WLAN AP composite apparatus illustrated in FIG. 4 provides a relay service as a WLAN AP by processing of the network processor 410 and simultaneously shares the HDD medium 465 by the operation of the system processor 480. Provides data server services provided by.

5 is a diagram illustrating a configuration of connecting an antenna in a WLAN AP composite device according to an embodiment of the present invention. As described above with reference to FIGS. 1 and 4, the system module 595 and the WLAN module 500 are composed of different PCB boards and connected through a specific connector mechanism 560, which in FIG. An embodiment using the connector mechanism of the DIP) type is shown. In addition, in the embodiment of FIG. 5, the RF shield case 505 is mounted on the RF element in order to keep the characteristics of the RF communication modules 120 to 155 and 420 to 455 to be satisfactory and to minimize noise input.

In the WLAN technology, it is more preferable to use a diversity type antenna in order to improve reception performance. For this purpose, the WLAN module 500 may include first and second SMD connectors for connecting the main antenna and the diversity antenna. 541, 542). Since the main antenna and the diversity antenna should be mounted outside the WLAN AP composite device, first and second SMA connectors 541 and 542 for mounting these antennas are provided on the external surface of the WLAN AP composite device. The first and second SMD connectors 541 and 542 and the first and second SMA connectors 541 and 542 are connected via coaxial cables 535 and 536, respectively, and coaxial cables are provided at the ends of the coaxial cables 535 and 536. Couplings 533 and 534 are provided for connecting 535 and 536 to the first and second SMD connectors 541 and 542.

According to the WLAN AP composite apparatus of the present invention, by separating the WLAN module and the system module, it is possible to shorten the software development period of the system and improve the overall system performance. The MAC mode MII interface is connected to the system processor and the Ethernet PHY so that the WLAN AP composite device can be implemented in a small form as a simple hardware configuration.

Claims (6)

delete RF communication modules 120 to 155 for providing RF communication for wireless LAN connection, and perform external WLAN communication by performing WLAN medium access control and wireless LAN baseband processing for the RF communication module, and provide a MAC mode. Provides wired LAN communication by performing a wired LAN media access control on an external Ethernet PHY through a configured second MII-IF port, and the wireless LAN communication and the wired LAN communication with respect to a main system through a first MII-IF port configured in a PHY mode. A network processor 110 which provides a connection to the network processor and performs relay processing to provide a relay service between the WLAN communication and the wired LAN communication, and stores an execution program code of the network processor and performs an operation of the execution program. Memory module 115 that provides the required memory space, and external to provide RF media access by the RF communication module WLAN module comprising at least one internal connector for connecting a WLAN antenna (531, 532) (100); It provides an external cable connection through an Ethernet port and is connected to a second MII-IF port of the network processor through a fourth MII-IF port set in PHY mode when the wireless LAN module is connected to the wired LAN physical network. An Ethernet PHY 170 providing a connection, and a third MII-IF port configured to control the operation of the system and set to a MAC mode, thereby enabling the first MII- of the network processor to be connected to the WLAN module. Connected to an IF port to receive a wired or wireless LAN connection from the network processor, and when connected to the wireless LAN module, connected to a fourth MII-IF port of the Ethernet PHY to receive a wired LAN connection from the Ethernet PHY. A system program connected to the network processor through an IF or serial communication IF to perform mutual data exchange and / or mutual or unilateral operation control. Stand 180, the main system 190 to perform the system operation in response to the control of the system processor, and the external wireless LAN antenna is installed on the external surface of the device for fixed mounting to the wireless module of the A system module 195 including one or more external connectors 541 and 542 each connected to one or more internal connectors; And Providing a mechanical fastening between the WLAN module and the system module, wherein the fastening electrically connects the fourth MII-IF port of the Ethernet PHY and the second MII-IF port of the network processor. 3 electrically connects a MII-IF port to a first MII-IF port of the network processor; and, if not, an electrical connection between a third MII-IF port of the system processor and a fourth MII-IF port of the Ethernet PHY. Connecting member 160 to enable this Wireless LAN AP composite device comprising a. RF communication modules 420 to 455 for providing RF communication for wireless LAN access, and perform external WLAN communication by performing WLAN medium access control and wireless LAN baseband processing for the RF communication module, and provide a MAC mode. Provides wired LAN communication by performing a wired LAN media access control on an external Ethernet PHY through a configured second MII-IF port, and the wireless LAN communication and the wired LAN communication with respect to a main system through a first MII-IF port configured in a PHY mode. A network processor 410 which provides a connection to the network processor and performs relay processing to provide a relay service between the WLAN communication and the wired LAN communication, and stores an execution program code of the network processor and performs an operation of the execution program. Memory module 415, which provides the required memory space, and external cable access through an external Ethernet port. The Ethernet PHY 470 connected to the second MII-IF port of the network processor through the fourth MII-IF port configured in the PHY mode when the WLAN module is connected to the WLAN module provides a wired LAN physical connection to the network processor. And a wireless LAN module 400 including one or more internal connectors 531 and 532 for connecting an external wireless LAN antenna for providing RF medium access by the RF communication module. A third MII-IF port configured to control the operation of the system and set to a MAC mode is connected to the first MII-IF port of the network processor when the wireless LAN module is connected to the wireless LAN module. Is connected to the fourth MII-IF port of the Ethernet PHY and is provided with a wired LAN connection from the Ethernet PHY when not connected to the WLAN module, and is connected to the network processor through a control IF or a serial communication IF. A system processor 480 connected to perform mutual data exchange and / or mutual or one-way operation control, a main system 490 performing system operation in response to control of the system processor, and an external WLAN antenna are connected. One that is installed on the external surface of the device for fixed mounting by being connected to one or more internal connectors of the WLAN module System module (495) containing on the outer connector (541, 542); And A connecting member 460 connecting the WLAN module and the system module and electrically connecting a third MII-IF port of the system processor and a first MII-IF port of the network processor. Wireless LAN AP composite device comprising a. delete delete delete