CN212012687U - Distributed MESH WIFI6 router with storage function - Google Patents
Distributed MESH WIFI6 router with storage function Download PDFInfo
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- CN212012687U CN212012687U CN202020783207.1U CN202020783207U CN212012687U CN 212012687 U CN212012687 U CN 212012687U CN 202020783207 U CN202020783207 U CN 202020783207U CN 212012687 U CN212012687 U CN 212012687U
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Abstract
The utility model discloses a distributed MESH WIFI6 router with memory function, the first end of its net gape PHY module is passed through the RJ45 interface and is connected with outside ethernet communication equipment, and the other end passes through the PSGMII interface and is connected with the CPU module. One end of the WIFI6 wireless transmission module is connected with the CPU module through an A/D interface, and the other end of the WIFI6 wireless transmission module is in wireless communication connection with an external user terminal and another distributed MESH WIFI6 router with a storage function. One end of the network disk module is connected with the CPU module through a USB3.0 interface, and the other end of the network disk module is connected with the hard disk through an SATA interface. The utility model has the advantages that: the distributed MESH WIFI6 routers with the storage function can be automatically networked through WIFI, the user terminal can be switched and connected among the distributed MESH WIFI6 routers with the storage function without disconnection, and the problem of difficulty in wiring is solved. Moreover, the distributed MESH WIFI6 router with the storage function has the function of storing user data, and user experience is greatly improved.
Description
Technical Field
The utility model relates to a technical field of router, in particular to distributed MESH WIFI6 router with memory function.
Background
Each of the conventional common routers needs to receive respective data from an external network device through a network cable, and then wirelessly transmit respective data signals to a user terminal through a routing terminal. Because the signal coverage of each existing common router is limited, the common routers cannot be directly communicated with each other to be networked, and the signal full coverage can be realized by arranging a plurality of common routers indoors with large space, so that the wiring is difficult, and the signal interference between WIFI is caused. In addition, the existing common router has a single function, does not have the function of storing user data, and cannot meet the storage requirement of a user.
SUMMERY OF THE UTILITY MODEL
Problem to prior art existence, the utility model aims at providing a distributing type MESH WIFI6 router with memory function aims at solving current ordinary router and can not directly carry out the communication connection each other and the network deployment, and it is difficult to lay wire when leading to a plurality of ordinary routers of the great indoor installation in space, and the problem that user's data can not be stored to current ordinary router.
To achieve the above object, the utility model provides a distributed MESH WIFI6 router with memory function, include: the system comprises a CPU module, and a network port PHY module, a WIFI6 wireless transmission module, a network disk module and a power management module which are respectively connected with the CPU module. The first end of the network port PHY module is connected with external Ethernet communication equipment through an RJ45 interface, and the other end of the network port PHY module is connected with the CPU module through a PSGMII interface. One end of the WIFI6 wireless transmission module is connected with the CPU module through an A/D interface, and the other end of the WIFI6 wireless transmission module is in wireless communication connection with an external user terminal and another distributed MESH WIFI6 router with a storage function. One end of the network disk module is connected with the CPU module through a USB3.0 interface, and the other end of the network disk module is connected with the hard disk through an SATA interface. The power supply management module is connected with the CPU module in a power supply mode and used for supplying power to the CPU module.
Preferably, the CPU module includes: SOC chip, DDR3 chip and FLASH chip. The DDR3 chip is connected with the SOC chip through a DDR protocol interface, and the FLASH chip is connected with the SOC chip through an SPI protocol interface. The model of the SOC chip is IPQ6000, the model of the DDR3 chip is MT41K256M16TW, and the model of the FLASH chip is W25Q128 JWEIQ.
Preferably, the network port PHY module is a QCA8075 chip, and the QCA8075 chip is connected to the SOC chip through a PSGMII interface.
Preferably, the WIFI6 wireless transmission module includes: a QCN5021 chip and a QCN5152 chip. The QCN5021 chip and the QCN5152 chip are connected with the SOC chip through an A/D interface.
Preferably, the mesh panel module includes: ASM1153 chips and hard disks. One end of the ASM1153 chip is connected with the SOC chip through a USB3.0 interface, and the other end of the ASM1153 chip is connected with the hard disk through a SATA interface.
Preferably, the power management module comprises: the power supply chips with the models of MP5496 and MP1653 are connected with the SOC chip respectively.
Compared with the prior art, the beneficial effects of the utility model reside in that: after a plurality of distributed MESH WIFI6 routers with storage functions are installed in a large room, only one of the distributed MESH WIFI6 routers with storage functions needs to receive data from external network equipment through a network cable, and the other distributed MESH WIFI6 routers with storage functions can be automatically networked through WIFI, so that a user terminal can be switched and connected between the distributed MESH WIFI6 routers with storage functions without disconnection, seamless roaming of data signals is realized, no dead angle is covered, and the problem of difficulty in wiring is solved. Moreover, the distributed MESH WIFI6 router with the storage function can realize the function of storing user data by arranging the network disk module, so that the user experience is greatly improved.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.
Fig. 1 is a schematic structural diagram of an embodiment of the present invention;
FIG. 2 is a schematic diagram of the distribution of the present invention;
the purpose of the present invention is to provide a novel and improved method and apparatus for operating a computer.
Detailed Description
The utility model provides a distributed MESH WIFI6 router with memory function.
Referring to fig. 1-2, fig. 1 is a schematic structural diagram of an embodiment of the present invention, and fig. 2 is a schematic diagram of the present invention during distribution.
As shown in fig. 1, in the embodiment of the present invention, the distributed MESH WIFI6 router with storage function includes: the wireless power supply comprises a CPU module 100, and a network port PHY module 200, a WIFI6 wireless transmission module 300, a network disk module 400 and a power supply management module 500 which are respectively connected with the CPU module 100.
The CPU module 100 includes: the chip comprises an SOC chip, a DDR3 chip and a FLASH chip, wherein the model of the SOC chip is IPQ6000, the model of the DDR3 chip is MT41K256M16TW, and the model of the FLASH chip is W25Q128 JWEIQ. The DDR3 chip is connected with the SOC chip through a DDR protocol interface, and the FLASH chip is connected with the SOC chip through an SPI protocol interface.
The SOC chip in the CPU module 100 mainly processes data transmitted from the network port PHY module 200 and the WIFI6 wireless transmission module 300, and manages data in the network disk module 400. The DDR3 chip and the FLASH chip are used for cooperatively processing data in a transmission process and storing system data.
The SOC chip with the model of IPQ6000 supports 802.11ax/ac/a/n/p wireless transmission protocol of 5/10/20/40/80/80+80MHz, supports 2X2 MU-MIMO wireless data transmission, 1201Mbps (5GHz) and 573.5Mbps (2.4GHz), and the transmission rate of a single maximum spatial stream with 80MHZ bandwidth can reach 600.5Mbps in a 1024-QAM modulation mode.
The PHY module 200 is a QCA8075 chip, a first end of the QCA8075 chip is connected to an external ethernet communication device through an RJ45 interface, and another end of the QCA8075 chip is connected to the SOC chip through a PSGMII interface. The QCA8075 chip processes data transmitted from an external ethernet network by using a two-layer switching technology, so that the data can be effectively transmitted between a network layer and a data link layer.
The WIFI6 wireless transmission module 300 includes: a QCN5021 chip and a QCN5152 chip. The first ends of the QCN5021 chip and the QCN5152 chip are respectively connected with the SOC chip through the corresponding A/D interfaces, the second ends of the QCN5021 chip and the QCN5152 chip are in wireless communication connection with an external user terminal and in wireless communication connection with other external distributed MESH WIFI6 routers with the storage function.
The SOC chip is connected with the WIFI 2.4GHz chip through an A/D interface and is converted into RF, RF signal amplification and receiving and transmitting SWITCH switching are completed through 2.4G FEM (PA/LNA/SWITCH), and wireless communication with the user terminal and other distributed MESH WIFI6 routers with the storage function is achieved through antenna transmission or reception. The SOC chip is connected with the WIFI 5GHz chip through an A/D interface, and 5G WIFI conversion is completed. RF signal amplification and receiving and transmitting SWITCH switching are completed through 5G FEM (PA/LNA/SWITCH), and then wireless communication with a user terminal and other distributed MESH WIFI6 routers with storage functions is realized through antenna transmission or reception.
The network disk module 400 includes: ASM1153 chips and hard disks. One end of the ASM1153 chip is connected with the SOC chip through a USB3.0 interface, and the other end of the ASM1153 chip is connected with the hard disk through a SATA interface. The USB3.0 is converted into SATA signals through an ASM1153 chip, and storage exchange with a hard disk is realized, so that a large-capacity storage space is provided.
The power management module 500 is connected to the CPU module 100 for supplying power to the CPU module 100. In this embodiment, the power management module 500 includes: and power supply chips with MP5496 and MP1653 models respectively connected with the SOC chip. In the embodiment of the present invention, the MP5496 power chip and the MP1653 complete the management of the power system together.
As shown in fig. 2, when a plurality of distributed MESH WIFI6 routers with storage function are installed in a large room, one of the distributed MESH WIFI6 routers with storage function is connected to an external network device through a network cable to receive data. Specifically, in this embodiment, the ethernet communication device is the PON device 600. The distributed MESH WIFI6 router with storage function connected to the PON device 600 is called a master. The remaining distributed MESH WIFI6 routers with storage function we call children.
Then, the master unit and the slave units are arranged so that one master unit can be connected to a plurality of slave units. Specifically, the submachine is placed in a strong signal range (such as a distance of 1 meter) of the master machine, the submachine and the master machine can be automatically paired, and then automatic networking can be realized after pairing, so that the signal coverage range is expanded.
When all the submachine are within the signal coverage range of the master machine, each submachine is preferably connected with the master machine as long as the power supply is connected. If one of the submachine needs to be arranged beyond the signal coverage range of the master machine, the two submachine can be automatically paired and networked only by arranging the submachine in the signal coverage range of the other submachine, and then a bridging network with a wider coverage range is formed.
The embodiment of the utility model provides an in, through adopting 2.4GHz/5GHz dual-frenquency unification, each user terminal connects an SSID, just can carry out automatic switch-over in all submachine and mother's machine signal coverage, also can not break the net, seamless roaming covers no dead angle.
For example, when one user terminal is in the signal coverage range of two slave units, the master unit can analyze the signal intensity of the user terminal, and the user terminal is switched to be connected to the slave unit with a better signal. So that the best signal connection is always selected.
If the terminal is in the signal coverage range of the slave unit and the master unit at the same time, the terminal is preferably connected with the master unit, and the bridging times are reduced.
Compared with the prior art, the beneficial effects of the utility model reside in that: through setting up the SOC chip that the model is IPQ6000 to and WIFI6 wireless transmission module 300 that QCN5021 chip and QCN5152 chip are constituteed, and be connected SOC chip and WIFI6 wireless transmission module 300 through the AD interface, make each have the automatic network deployment of each other accessible WIFI of distributed MESH WIFI6 router of memory function and connect. Therefore, after a plurality of distributed MESH WIFI6 routers with storage functions are installed in a room with a large space, only one of the distributed MESH WIFI6 routers with storage functions needs to receive data from external network equipment through a network cable. The distributed MESH WIFI6 routers with the storage function are automatically networked through WIFI, so that the user terminal can be switched and connected among the distributed MESH WIFI6 routers without disconnection, seamless roaming of data signals is achieved, no dead angle is covered, and the problem of difficulty in wiring is solved. Moreover, the distributed MESH WIFI6 router can realize the function of storing user data by arranging the network disk module 400, so that the user experience is greatly improved.
The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.
Claims (6)
1. A distributed MESH WIFI6 router with storage function, comprising: the system comprises a CPU module, a network port PHY module, a WIFI6 wireless transmission module, a network disk module and a power management module which are respectively connected with the CPU module; the first end of the network port PHY module is connected with external Ethernet communication equipment through an RJ45 interface, and the other end of the network port PHY module is connected with the CPU module through a PSGMII interface; one end of the WIFI6 wireless transmission module is connected with the CPU module through an A/D interface, and the other end of the WIFI6 wireless transmission module is in wireless communication connection with an external user terminal and another distributed MESH WIFI6 router with a storage function; one end of the network disk module is connected with the CPU module through a USB3.0 interface, and the other end of the network disk module is connected with a hard disk through an SATA interface; the power management module is connected with the CPU module in a power supply mode and used for supplying power to the CPU module.
2. The distributed MESH WIFI6 router with storage functionality of claim 1, wherein said CPU module comprises: SOC chip, DDR3 chip and FLASH chip; the DDR3 chip is connected with the SOC chip through a DDR protocol interface, and the FLASH chip is connected with the SOC chip through an SPI protocol interface; the model of the SOC chip is IPQ6000, the model of the DDR3 chip is MT41K256M16TW, and the model of the FLASH chip is W25Q128 JWEIQ.
3. The distributed MESH WIFI6 router with storage capability of claim 2, wherein the MESH PHY module is a QCA8075 chip, and the QCA8075 chip is connected to the SOC chip via a PSGMII interface.
4. The distributed MESH WIFI6 router with storage capability of claim 2, wherein the WIFI6 wireless transmission module comprises: a QCN5021 chip and a QCN5152 chip; the QCN5021 chip and the QCN5152 chip are connected with the SOC chip through an A/D interface.
5. The distributed MESH WIFI6 router with storage functionality of any one of claims 2-4, wherein the network disk module comprises: an ASM1153 chip and a hard disk; one end of the ASM1153 chip is connected with the SOC chip through a USB3.0 interface, and the other end of the ASM1153 chip is connected with the hard disk through an SATA interface.
6. The distributed MESH WIFI6 router with storage functionality of claim 2, wherein the power management module comprises: the power supply chips with the models of MP5496 and MP1653, the power supply chip of MP5496 and the power supply chip of MP1653 are connected with the SOC chip.
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| CN202020783207.1U CN212012687U (en) | 2020-05-12 | 2020-05-12 | Distributed MESH WIFI6 router with storage function |
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| CN202020783207.1U CN212012687U (en) | 2020-05-12 | 2020-05-12 | Distributed MESH WIFI6 router with storage function |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113766021A (en) * | 2021-09-02 | 2021-12-07 | 深圳市中科联合通信技术有限公司 | High-speed communication device for converting 5G NR3GPP mobile data into 802.11ax WIFI6 |
| CN113852965A (en) * | 2021-09-09 | 2021-12-28 | 深圳市中科联合通信技术有限公司 | Device for realizing cellular networking based on 802.11ax WiFi6 technology |
-
2020
- 2020-05-12 CN CN202020783207.1U patent/CN212012687U/en active Active
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113766021A (en) * | 2021-09-02 | 2021-12-07 | 深圳市中科联合通信技术有限公司 | High-speed communication device for converting 5G NR3GPP mobile data into 802.11ax WIFI6 |
| CN113852965A (en) * | 2021-09-09 | 2021-12-28 | 深圳市中科联合通信技术有限公司 | Device for realizing cellular networking based on 802.11ax WiFi6 technology |
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