RU190237U1 - Subscriber Network Device with Virtualized Network Functions - Google Patents

Abstract

The utility model relates to data transmission systems, in particular, to systems using subscriber network device virtualization (vCPE) .1. A device containing a microcontroller, read-only memory, random access memory, connected by an address and data bus to a microcontroller, first power supply unit, characterized in that it additionally introduces a high-speed packet data processing module with non-blocking high-speed FPGA switching matrix the first input / output of which is connected by bus to the first microcontroller, Ethernet transceiver modules (PHY), the first inputs / outputs of which are connected by bus to the second inputs / outputs high-speed packet data processing module with non-blocking high-speed FPGA-based switching matrix (FPGA); information input / output ports, the first inputs / outputs of which are connected to the second inputs / outputs of the Ethernet transmit-receive modules (PHY), and the second inputs / outputs are the inputs / outputs of the device; the power supply system of the remote control and management unit, the first input / output of which is connected to the fourth input / output of the microcontroller; a block of switched power supplies comprising the first and second power supplies, the first controlled relay, whose input is connected to the second output of the remote control and monitoring unit; the second controlled relay, the input of which is connected to the output of the switching power supply unit; PoE power injector, the output of which is connected with the open contact of the second controlled relay, and the input through the RG45 connector with the power transmission line through the standard twisted pair on an Ethernet.2 network. The device according to claim 1, characterized in that all its elements are made using digital technology.

Description

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

Telecom operators are looking for new ways to generate revenue streams, more flexible organization of service provision, reduction of infrastructure maintenance costs and automation of management. The answer to such 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 is vCPE (virtual Customer Premises Equipment or “virtualization of subscriber network devices”).

One of the main approaches to the implementation of vCPE is the Edge model, where all virtual functions are placed on the client side on an inexpensive device (a micro server with a sufficient number of Ethernet ports), which is a local NFV infrastructure (NFVI) for a specific customer. When using the approach of creating a small virtual infrastructure on client devices, there is no need for a huge pool of resources and costs appear only at the moment when the customer orders the service.

The closest technical solution that meets the requirements of the virtualization of subscriber network devices is the device described in the article “Evaluation of the effectiveness of network processor architectures” (Grischenko VI, Ladyzhenskiy Yu.V., Younis M. Main directions for the development of modern network processors / D. D. Morgaylov, Yu.V. Ladyzhensky, M. Yunis // Naukovi Pratsi DonNTU. - Donetsk, 2011. - (Series “Informatics, Cybernetics and Observational Technique"). - №14 (188). - p. 123-127 .) - prototype.

This device contains a microcontroller, a persistent storage device, a random access memory, connected by an address and data bus to the microcontroller, the first power supply unit.

In order to create a highly reliable power supply system for the device in question, it is proposed, in addition to the existing power supply system (when the latter fails), to transmit vCPE electrical energy through a standard twisted pair on an Ethernet network using Power over Ethernet technology. It is known that this technology is intended for IP-telephony, access points of wireless networks, IP cameras, network hubs and other devices to which it is undesirable or impossible to conduct a separate electrical cable.

The goal of the utility model is to create a highly reliable power supply system, when, along with redundant power supplies, an additional power supply line is used over a standard twisted pair cable on an Ethernet network using PoE technology.

This goal is achieved in that the device containing the microcontroller, read-only memory, random access memory, the address and data bus connected to the microcontroller, the first power supply unit, characterized in that it additionally introduces a high-speed packet data processing module with an unblockable high-speed switching matrix. based on FPGA (FPGA), the first input / output of which is connected by bus to the first microcontroller, Ethernet receiving-transmitting modules (PHY), the first inputs / outputs of which are soy bus lines with second inputs / outputs of high-speed packet data processing module with non-blocking high-speed FPGA-based switching matrix; information input / output ports, the first inputs / outputs of which are connected to the second inputs / outputs of the receive-transmitting Ethernet modules (PHY), and the second inputs / outputs are the inputs / outputs of the device; the power supply system of the remote control and management unit, the first input / output of which is connected to the fourth input / output of the microcontroller; a block of switched power supplies comprising the first and second power supplies, the first controlled relay, whose input is connected to the second output of the remote control and monitoring unit; the second controlled relay, the input of which is connected to the output of the switching power supply unit; PoE power injector, the output of which is connected to the open contact of the second controlled relay, and the input through the RG45 connector to the power transmission line through the standard twisted pair on an Ethernet network.

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

Comparison of the proposed solution with other technical solutions shows that the listed elements used in the blocks are known, but their introduction in this connection with the other elements leads to the creation of a highly reliable power supply system, when along with redundant power supplies an additional link is established with the power supply transmission line via standard twisted pair on an Ethernet network. This confirms the compliance of the technical solution with the criterion of "significant differences".

FIG. 1 shows the proposed device consisting of: microcontroller (CPU) 1, high-speed packet data processing module with non-blocking high-speed FPGA-based switching matrix 2, random access memory (RAM) 4, read-only memory (ROM) 3, receiving and transmitting Ethernet modules (PHY) 5, information input / output ports 6; a power system consisting of a switching power supply unit BP1, BP2 (7), a remote control unit and control unit 8, a first controlled relay P1 9, a second controlled relay P2 10, a PoE 11 power injector.

The proposed device works as follows.

To connect remote offices, divisions, etc., which have their own local network using point-to-point, point-to-multipoint and multipoint-to-multipoint services, installation of special equipment is required, placed on the customer’s side, but served centrally (for example, by the service provider or central office). In this case, the most modern approach is to introduce the SDN / SD-WAN concept and support NFV services implemented centrally (for example, in the data center of the operator) or distributed (both on vCPE and 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, subscriber equipment virtualization is needed through the use of 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 faces the task of implementing additional functions — for example, to monitor and manage connections and traffic, to solve customer’s business problems, etc. For example, 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 corresponding equipment on the client side. NFV helps to solve this problem in a much more efficient way, namely, by virtualizing network functions in software applications that can be run both on regular servers and on virtual machines running on these servers. In this case, the operator can, using only one network interface device to delimit the 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 to build the SD-WAN architecture network by telecom operators and for corporate networks. For this purpose, vCPE devices are used that are installed on the customer’s network side and allow implementation of the SDN approach to network management and service implementation in accordance with the NFV ideology.

For the implementation of a subscriber network device with virtualized network functions (vCPE), a well-known network processor building structure (prototype) with a central processor (CPU) 1, connected tires with a permanent memory (ROM) 3 and random access memory (RAM) 4 was taken. Using ICs FPGA 2 provides the necessary flexibility in developing the hardware logic for processing network traffic, as well as the possibility of implementing additional functionality when the competitive environment changes without changing the architecture devices.

Ethernet Transceiver Modules (PHY) 5 is an integrated circuit designed to perform the functions of the physical layer of the OSI network model.

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

Power system operation.

In the initial state, the block of switched power supplies consisting of BP1 and BP2 (7) is disconnected. When the power supply unit BP1 needs to be connected, the first controlled relay P1 9 is turned on, the normally closed contacts of which connect the output voltage from BP1 to the second controlled relay P2 10, whose normally closed contacts connect the output of the supply voltage to the elements of the subscriber network device with virtualized network functions.

The remote monitoring and control unit 8 is an active network device that performs reception, transmission and processing of signals based on network protocols (for example, TCP / IP protocols).

In addition, the proposed device uses an additional line for supplying voltage from an external source through a standard twisted pair on an Ethernet network. This ensures uninterrupted operation of the device when the main supply voltage of 220 V. disappears.

When the main power is disconnected, the controlled relay P2 10 is de-energized and its contact group is connected to the output of the PoE 11 power injector, thereby ensuring the supply of supply voltage to the device elements.

The PoE technology is described by IEEE 802.3af-2003 and IEEE 802.3at-2009 standards. The power supply unit (PSE) supplies power to the cable only if the device being connected is a powered type device. Thus, equipment that does not support PoE technology and is accidentally connected to the power supply will not be incapacitated. The procedure for applying and disconnecting power to a cable consists of several steps.

1. Definition of connection.

The connection detection step is used to determine whether a device connected at the opposite end of the cable is powered (PD). At this stage, the power supply device (PSE) supplies the cable with voltage from 2.8 to 10 V and determines the parameters of the input resistance of the connected device. For a powered device, this resistance ranges from 19 to 26.5 kΩ with a parallel-connected capacitor with a capacity from 0 to 150 nF. Only after checking the compliance of the input resistance parameters for the powered device, the powering device proceeds to the next stage, otherwise the powering device re-tries to determine the connection after a period of at least 2 ms.

2. Apply full voltage.

After passing the stages of determination and classification, the power supply device supplies 48 V to the cable with a rising edge not faster than 400 ms. After applying a full voltage to a powered device, the feeding device monitors its operation in two ways:

- if the powered device will consume less than 5 mA for 400 ms, then the feeding device removes power from the cable;

- the power supply unit supplies to the cable a voltage of 1.9-5.0 V with a frequency of 500 Hz and calculates the input resistance; if this resistance is greater than 1980 kΩ for 400 ms, the power supply removes power from the cable.

In addition, the supply device continuously monitors the overload current. If the powered device consumes more than 400 mA of current for 75 ms, the powering device will remove power from the cable.

3. Shutdown.

When the power supply device determines that the powering device is disconnected from the cable or an overload of the consumed current by the powered device occurs, the voltage is removed from the cable for at least 500 ms.

The PoE technology makes it possible to use centralized uninterruptible power supplies to ensure power supply to the devices in case of general power failures. This becomes all the more important as more data is transmitted over Ethernet networks related to security systems, access control and management of various engineering equipment of a building, and in addition, the control capabilities of end devices that can be turned off or reloaded remotely are improved.

The maximum current in a normal operating mode of a PSE device is 350 mA per pair or 175 mA per conductor. These characteristics were calculated taking into account the maximum load capacity of a cable consisting of 26 AWG conductors (approximately 0.4 mm in diameter) at the maximum allowable operating temperature. It is stipulated that when the power is turned on for the first millisecond, the current consumed by the terminal device can reach 5 A, and then another 50 ms to remain at 450 mA.

Thus, a subscriber network device with virtualized network functions with a highly reliable power supply system provides, in the event of a power failure, a transition to an independent line with power supply from an external source through a standard twisted pair on an Ethernet network.

Claims (2)

1. Subscriber network device with virtualized network functions, containing a microcontroller, read-only memory, random access memory, connected by an address and data bus to a microcontroller, first power supply, characterized in that it additionally introduces a high-speed packet data module with a non-blocking high-speed matrix FPGA-based switching (FPGA), the first input / output of which is connected by bus to the first microcontroller, Ethernet transceiver modules (PHY), the first in the strokes / outputs of which are connected by bus to the second inputs / outputs of the high-speed packet data processing module with non-blocking high-speed FPGA-based switching matrix; information input / output ports, the first inputs / outputs of which are connected to the second inputs / outputs of the Ethernet transmit-receive modules (PHY), and the second inputs / outputs are the inputs / outputs of the device; the power supply system of the remote control and management unit, the first input / output of which is connected to the fourth input / output of the microcontroller; a block of switched power supplies comprising the first and second power supplies, the first controlled relay, whose input is connected to the second output of the remote control and monitoring unit; the second controlled relay, the input of which is connected to the output of the switching power supply unit; PoE power injector, the output of which is connected to the open contact of the second controlled relay, and the input through the RG45 connector to the power transmission line through the standard twisted pair on an Ethernet network. 2. The device according to p. 1, characterized in that all its elements are made using digital technology.

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