RU179300U1 - Subscriber network device with virtualized network functions - Google Patents

Abstract

The utility model relates to subscriber network devices (vCPE). The technical result is to expand the functions of the device. A device with virtualized network functions, contains a microcontroller, read-only memory, random access memory, connected to the microcontroller bus, information input ports connected by the address and data bus to the microcontroller, characterized in that a Wi-Fi unit, an indication unit are additionally inserted into it, GPS Tracker connected to the address and data bus with a microcontroller, an ambient temperature sensor, a temperature sensor for the cooling system, the outputs of which are connected to the inputs of the corresponding pores information input module, high-speed packet data processing module with a non-blocking high-speed FPGA-based switching matrix, the first input / output of which is connected by a bus to the microcontroller, Ethernet transceiver modules, the first inputs / outputs of which are connected by a bus to the second inputs / outputs of the high-speed processing module packet data with non-blocking high-speed FPGA-based switching matrix, information input / output ports, the first inputs of which are connected to the second inputs / outputs of the transceiver m Ethernet modules, and the second inputs / outputs are the inputs / outputs of the device. 1 s.p. f-ly, 2 ill.

Description

The utility model relates to data transmission systems, in particular to systems using subscriber network device virtualization (vCPE).

Telecommunications operators are looking for new ways to generate revenue streams, more flexible organization of service delivery, reducing infrastructure maintenance costs and management automation. The answer to these needs is the concept of NFV (Network Function Virtualization) - virtualization of network functions. Solution developers are trying to offer operators new business cases that would make the use of technology cost-effective. Among the potentially attractive cases vCPE stands out (virtual Customer Premises Equipment or “virtualization of subscriber network devices”).

One of the main approaches to implementing vCPE is the Edge model, where all virtual functions are located on the client side on an inexpensive device (micro-server with a sufficient number of Ethernet ports), which is a local NFV infrastructure (NFVI) for a specific customer. When using the approach with creating a small virtual infrastructure on client devices, you do not need a huge pool of resources and costs appear only at the moment when the client orders the service.

The closest technical solution that meets the requirements of virtualization of subscriber network devices is the device described in the article "Evaluation of the effectiveness of network processor architectures" (Grishchenko V.I., Ladyzhensky Yu.V., Yunis M. The main directions of development of modern network processors / D. D. Morgailov, Yu.V. Ladyzhensky, M. Yunis // Science and technology, DonNTU. - Donetsk, 2011. - (Series "Informatics, cybernetics and obucenuvlya tekhnika"). - No. 14 (188). - pp. 123-127 .) is a prototype.

This device contains a microcontroller, read-only memory, random-access memory, connected to the microcontroller by the bus, information input ports connected by the address and data bus to the microcontroller.

The purpose of the utility model is to expand the functions of the device and ensure its safety.

This goal is achieved by the fact that in the device containing the microcontroller, read-only memory, random access memory, connected by a bus to the microcontroller, information input ports connected by the address and data bus to the microcontroller

Wi-Fi unit, display unit, GPS Tracker, connected to the address and data bus with the microcontroller,

ambient temperature sensor, temperature sensor of the cooling system, the outputs of which are connected to the inputs of the corresponding information input ports,

a high-speed packet data processing module with a non-blocking high-speed FPGA-based switching matrix, the first input / output of which is connected to the microcontroller by a bus,

Ethernet transceiver modules, the first inputs / outputs of which are connected by bus to the second inputs / outputs of the high-speed packet data processing module with a non-blocking high-speed FPGA-based switching matrix,

information input / output ports, the first inputs of which are connected to the second inputs / outputs of the Ethernet transceiver modules, and the second inputs / outputs are the inputs / outputs of the device.

Comparison with the prototype shows that the inventive device is characterized by the presence of new units and their connections between them. Thus, the claimed system meets the criterion of "novelty."

A comparison of the proposed solutions with other technical solutions shows that the listed elements used in the blocks are known, however, their introduction in this connection with other elements leads to the expansion of the functionality of the device. This confirms the conformity of the technical solution to the criterion of "significant differences".

In FIG. 1 shows a block diagram of the proposed device, in FIG. 2 - disclosed the structure of GPS Tracker.

The device includes: microcontroller 1, high-speed packet data processing module with non-blocking high-speed FPGA-based switching matrix 2, read-only memory (ROM) 3, random access memory (RAM) 4, information input ports 5, Wi-Fi 6 unit , address and data bus 7, display unit 8, GPS Tracker 9 consisting of: GPS antennas 9-1, GSM antennas 9-2, GPS-module for receiving and determining coordinates 9-3, GSM-transceiver module 9-4, control unit and memory 9-5, SIM card reader 9-6, programming port 9-7, tamper sensor 9-8; an ambient temperature sensor 10, a temperature sensor for the cooling system 11, an Ethernet transceiver module 12, 13; information input / output ports 14.

The proposed device operates as follows.

To connect remote offices, departments, etc., having their own local area network, using point-to-point, point-to-multipoint, and multipoint-to-multipoint services, it is necessary to install special equipment located on the customer’s side, but serviced centrally (for example, by a service provider or central office). In this case, the most modern approach is the introduction of the SDN / SD-WAN concept and support for NFV services implemented centrally (for example, in the operator’s data center) or distributed (both on vCPE, on the core network, and in the data center).

The introduction of NFV will allow operators and large corporate customers to transform the network infrastructure by eliminating the use of specialized network equipment in favor of fully software and virtualized solutions.

To use NFV technology, virtualization of subscriber equipment is required by using vCPE. When connecting a new client, in addition to installing a demarcation device that separates the client’s network and the operator’s network, the service provider often has the task of implementing additional functions - for example, to control and manage connections and traffic, solve client business problems, etc. So, many corporate customers require additional features such as a firewall, VPN support, and DDoS protection.

In order to implement such services today, you need to deliver, install, configure, and then also maintain the appropriate equipment on the client side. NFV helps to solve this problem in a much more efficient way, namely due to virtualization of network functions in software applications that can be run both on ordinary servers and on virtual machines running on these servers. In this case, the operator can, using only one network interface device to differentiate traffic, “place” all other functions, such as a firewall, on its territory, and to simplify the network and manage it, in particular for building service chains, implement SDN.

The main purpose of the proposed device is the construction of the SD-WAN architecture network by telecom operators and for corporate networks. For this, vCPE devices are used that are installed on the customer’s network side and allow implementing the SDN approach to network management and service implementation according to the NFV ideology.

To implement a subscriber network device with virtualized network functions (vCPE), a well-known structure for building network processors (prototype) with a central processing unit (CPU) 1, an address and data bus 7 connected to information input ports 5, and buses with read-only memory (ROM) was taken 3 and random access memory (RAM) 4. CPU 1 is also connected via a bus to a non-blocking high-speed FPGA-based switching matrix 2. The use of FPGA 2 chips provides the necessary flexibility in the development of hardware logic brabotki network traffic, as well as the possibility of implementing additional functionality when changing competitive environment without modifying the device architectures.

The inputs of the input ports 5 (Fig. 1) are connected to the sensors of the ambient temperature 10 and the temperature of the cooling system vCPE 11, which allows you to control the temperature mode of the device through CPU 1. In addition, the address and data bus 7 is connected to the Wi-Fi unit 6, which provides wireless monitoring of the device status, with the display unit 8 and with GPS Tracker 9, designed to record unauthorized actions with the device (hacking, theft, etc.). The operation of this part of the device is controlled by CPU 1.

Ethernet Transceiver Modules (PHY) 12, 13 is an integrated circuit designed to perform the functions of the physical layer of the OSI network model.

PHYs allow other link-level chips, called MACs, to connect to a physical transmission medium, such as optical fiber or copper cable. The standard PHY microchip includes modules of the physical coding sublayer (PCS, Physical Coding Sublayer) and the transmission medium sublevel (PMD, Physical Medium Dependent). The physical coding sublevel module performs the functions of encoding and decoding the transmitted and received data stream. The purpose of coding is to simplify the process of recovering data stream by the receiver.

GSM Tracker 9 operation.

GSM Tracker is mounted in a subscriber switch. It refers to alarm systems and is used in the search and control of unauthorized movement of a vCPE device (for example, theft).

A global GPS positioning system and a GSM mobile communication system are used.

The general principles of GSM Tracker operation are as follows: GPS receiver 9-3 receives information from satellites of the global positioning system, this information is processed by the coordinate calculation unit and goes to the microprocessor control unit and memory 9-5. According to the commands of the control unit and memory 9-5 using a GSM transceiver 9-4, a message about the unauthorized movement of the switch is transmitted via the mobile network to the monitoring and control center. Information is transmitted in the form of SMS messages or in data transfer mode (Data Transfer Mode), and the identification of stand-alone subscriber switches is made using a SIM card (Subscriber Identification Module). From the point of view of minimizing the cost of operating the system, it is most advisable to use the GPRS service (General Packet Radio Service).

The GSM 9-4 module is designed to transmit information about the coordinates of the subscriber switch received from the GPS 9-3 module to a mobile phone or computer of the integrated monitoring and control center. The module operates in 4 frequency ranges: 850/900/1800/1900 MHz.

In case of unauthorized use of the device, the tamper sensor is triggered and alarm information is received at the monitoring and control center.

GPS Tracker allows you to determine the current location of the subscriber switch with an accuracy of 2.5 meters, as well as view through a special Internet application the path traveled by the object for a certain period of time.

GPS Tracker is equipped with several modules to ensure its effective operation. The main structural elements include:

1. The satellite signal receiver from the GPS navigation systems (USA) and / or GLONASS (Russia) 9-3, allowing to determine the spatial coordinates of the object.

2. GSM 9-4 transceiver module, providing packet data sending usually by means of GPRS-connection or SMS messages.

3. The control unit and memory 9-5, in which data is stored.

4. Built-in antenna GPS 9-1 and GSM 9-2.

5. SIM card reader 9-6.

6. Programming port 9-7.

7. Unauthorized access sensor 9-8.

Effective control is provided by a whole range of hardware and software.

Thus, the proposed network device with virtualized network functions performs the virtualization of subscriber equipment and controls its security.

Claims (2)

1. A device with virtualized network functions, comprising a microcontroller, read-only memory, random access memory, connected to the microcontroller bus, information input ports connected by the address and data bus to the microcontroller, characterized in that a Wi-Fi block is additionally introduced into it, a block indications, GPS Tracker connected to the address and data bus with the microcontroller, ambient temperature sensor, temperature sensor of the cooling system, the outputs of which are connected to the inputs of the corresponding information input ports, high-speed packet data processing module with a non-blocking high-speed FPGA-based switching matrix, the first input / output of which is connected by a bus to a microcontroller, Ethernet transceiver modules, the first inputs / outputs of which are connected by a bus to the second inputs / outputs of a high-speed processing module packet data with non-blocking high-speed FPGA-based switching matrix, information input / output ports, the first inputs of which are connected to the second inputs / outputs transceiver x Ethernet modules, and second inputs / outputs are input / output devices. 2. The device according to p. 1, characterized in that all its elements are made using digital technology.

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