KR101385390B1 - Sleep mode control method of terminal in epon system, and terminal implementing the same - Google Patents

Abstract

The present invention relates to a terminal for receiving a service interface from an optical network unit (ONU) and performing a sleep mode in an Ethernet passive optical network (EPON) system. The terminal includes: a network connection unit for communicating with the ONU, receiving downlink traffic from the ONU, transmitting uplink traffic to the ONU, and receiving a state message including the state information of the ONU; and a main processor for analyzing the state message received to the network connection unit, when a state of the ONU is in a sleep mode, switching into the sleep mode for inactivating internal components, which transmit a signal in an active state, and when downlink traffic is received from the ONU in a state of being switched into the sleep mode, switching into the active state again. According to the present invention, a sleep or active state of a terminal can be synchronized according to a sleep or active state of an ONU, in the sleep state control of the terminal in the EPON system, to enable the efficient sleep or active state operation of the terminal, thereby reducing unnecessary power consumption and efficiently reducing power consumption. [Reference numerals] (101) Terminal; (102) Main processor; (103) Sleep mode control unit; (104) Data processing unit; (105) Network connection unit; (107) Tx/Rx transceiving unit

Description

Sleep mode control method of terminal device in EPON system and terminal device for implementing the same {Sleep mode control method of terminal in EPON system, and terminal implementing the same}

Sleep mode operation method of a terminal in an Ethernet Passive Optical Network (EPON) including a terminal and an optical network unit (hereinafter referred to as "ONU") And structure.

Passive Optical Network (PON) technology to realize FTTx (Fiber-To-The-Curb / Home / Office) is the traffic generated from subscriber networks due to the increase of Internet users and the proliferation of various services such as voice, data, and multimedia. Bottlenecks can be solved.

An optical network unit (ONU) is an optical subscriber terminal device and refers to an end device of an optical communication network that provides a service interface to end users. ONU accommodates FTTC, FTTB (fiber to the building), FTTF (fiber to the floor) and FTTO (fiber to the office), making it highly accessible to users and providing a cable for transmitting analog signals from customers. It is the device that connects and the light facilities.

PON is a passive optical splitter between the operator and the ONU that does not require a power source, and splits the cable to each ONU. This method eliminates the need for power equipment and facility management for active devices required in AON (Active Optical Network), and reduces the cost of network construction by reducing the number of laying of optical cables.

PON technology is classified into Wavelength Division Multiplexed-PON (WDM-PON), Asynchronous Transfer Mode-PON (ATM-PON), and Ethernet PON (EPON) according to the data link layer technology used.

WDM-PON is a technology that transmits multiple wavelengths of optical signals through a single fiber, and because subscribers use independent wavelengths, they can provide bandwidth on a dedicated line level and provide a high level of security. However, there are technical difficulties for management and control according to subscriber-specific wavelength allocation.

ATM-PON has the advantage of easy support of quality of service (QoS) through ATM traffic control and management, but has the disadvantage of lack of video transmission capability, insufficient bandwidth, complexity, and high network configuration cost.

EPON, on the other hand, is an Ethernet protocol-based phone network that offers up to 1Gbps transmission bandwidth up and down through low-cost Ethernet equipment, which has advantages over other PON technologies in terms of compatibility and price.

In EPON, one OLT (Optical Terminator) and N ONUs (Optical Subscriber Terminal Units) are connected through a 1: N passive optical splitter to form a point-to-multipoint tree structure topology. The downlink signal originating from the OLT is transmitted by broadcasting because the OLT and N ONUs are connected in a 1: N point-to-multipoint structure.

The downlink signal passes through the passive optical splitter and is transmitted to all ONUs as the intensity is reduced to 1 / N. The ONU selects the data whose destination is its downlink signal, converts it into an electrical signal, and delivers it to each subscriber. The ONU collects the signals from each subscriber, converts them into optical signals, and delivers them to the OLT. The ONU is controlled by the OLT and can transmit data to the OLT only within the time slot allocated from the OLT.

S.H. announced in February 2013. Shah Newaz et al., “Adaptive Delay-Aware Energy Efficient TDM-PON,” Elsevier Computer Network, propose a method to enter sleep mode when there is no transmit / receive data of ONU in TDM-PON system.

In addition, the IEEE 802.3az standard EEE (Energy Efficient Ethernet) technology is based on the fact that the utilization rate of the Ethernet link is very low. We propose a method to reduce the energy consumed at the interface.

However, the sleep mode control structure of the terminal and the ONU is made independently without information about the state of each other. In the ONU, the terminal enters the sleep mode in consideration of only the transmission / reception traffic volume from the network without information on the state of the terminal, and the terminal enters the sleep mode in consideration of the transmission / reception traffic volume of the terminal only. Therefore, the terminal may operate in the activation mode even when the ONU immediately above is in the sleep mode. If the ONU is in the sleep mode, the terminal cannot transmit and receive data with the network, and thus the terminal consumes unnecessary power.

Patent Publication 10-2008-0053118

The present invention has been made to solve the above problems, and provides a method and structure for reducing unnecessary power consumption of the terminal by receiving the status information from the ONU to match the operation synchronization for the sleep mode of the ONU and the terminal. have.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention provides a service interface from an optical network unit (ONU) in an Ethernet-based passive optical network (hereinafter referred to as "EPON") system, and sleep mode. In a terminal device for implementing the communication with the ONU, receives downlink traffic (downlink traffic) from the ONU, transmits uplink traffic to the ONU, including the state information of the ONU Analyze the network connection receiving the status message and the status message received at the network connection to deactivate the internal component transmitting the signal in the active state if the ONU is in the sleep mode. And the downlink traffic is received from the ONU while the system is in the sleep mode. And a main processor to switch to the active state.

The network access unit includes a Rx unit for receiving downlink traffic from the ONU, a Tx / Rx transceiver including a Tx unit for transmitting uplink traffic to the ONU, and a MAC layer in the OSI 7 layer. MAC may be performed to perform operations in the region.

When the main processor analyzes the status message and determines that the ONU is in the sleep mode, the main processor performs a packet processing operation of three or more layers in the OSI 7 layer and a sleep mode controller that controls the Tx unit to be in a sleep mode. And a data processor for performing a packet transmission / reception operation in association with the MAC and the Tx / Rx transceiver.

In a method of operating a sleep mode of a terminal device provided with a service interface from an optical network unit (ONU) in an Ethernet based passive optical network (EPON) system of the present invention, When the terminal device receives a status message including status information of the ONU from the ONU in an active state, analyzing the status message to determine whether the ONU is in a sleep mode and the ONU is in a sleep mode. In this case, the terminal device includes switching to a sleep mode which is a mode for deactivating an internal component that transmits a signal.

When the terminal device receives downlink traffic from the ONU in a sleep mode state, the terminal device may further include switching back to an activated state.

According to the present invention, in the sleep state control of a terminal in an Ethernet-based passive optical subscriber network system, the sleep or activation state of the terminal is synchronized by synchronizing the sleep or activation state of the terminal according to the sleep or activation state of the ONU. Accordingly, it is possible to reduce unnecessary power consumption and to efficiently reduce power consumption.

1 is a block diagram illustrating an internal configuration of a terminal device in an EPON system according to an embodiment of the present invention.
2 is a flowchart illustrating a sleep mode operation method of a terminal device in an EPON system according to an embodiment of the present invention.
3 is a message flow and state diagram between an ONU and a terminal device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used for the same reference numerals even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Also, throughout this specification, when a component is referred to as "comprising ", it means that it can include other components, aside from other components, .

The present invention provides a service interface from an optical network unit (ONU) in an Ethernet-based passive optical network (EPON) system, and implements a sleep mode. It is about a method.

1 is a block diagram illustrating an internal configuration of a terminal device in an EPON system according to an embodiment of the present invention.

Referring to FIG. 1, the terminal device 101 of the present invention communicates with the ONU 110 in a manner of transmitting and receiving a packet, and receives a service interface from the ONU 110.

The terminal device 101 of the present invention includes a main processor 102 and a network connection unit 105.

Network connection 105 communicates with ONU 110, receives downlink traffic from ONU 110, transmits uplink traffic to ONU 110, and ONU 110. It serves to receive a status message containing the status information of.

The main processor 102 analyzes the status message received from the network connection 105, and if the state of the ONU 110 is in the sleep mode, the main processor 102 sends an internal component that transmits a signal in an active state. In the sleep mode, which is a mode for deactivation, and when the downlink traffic is received from the ONU 110 in the sleep mode, the mode is switched back to the active state.

In the present invention, the network connection unit 105 includes a Tx / Rx transceiver unit 107 and a MAC 106.

The Tx / Rx transceiver 107 includes an Rx unit 108 for receiving downlink traffic from the ONU 110 and a Tx unit 109 for transmitting uplink traffic to the ONU 110.

The MAC 106 performs an operation in the Media Access Control layer (MAC) layer in the Open System Interconnections (OSI) 7 layer. That is, the MAC 106 is a block that performs operations in the general layer 2 MAC area.

In the present invention, the main processor 102 includes a sleep mode controller 103 and a data processor 104.

When the sleep mode controller 103 analyzes the status message and determines that the ONU 110 is in the sleep mode state, the sleep mode controller 103 deactivates the Tx unit 109 and controls to switch to the sleep mode.

The data processor 104 performs a packet processing operation of three or more layers in the OSI 7 layer, and performs a packet transmission / reception operation in association with the MAC 106 and the Tx / Rx transceiver 107.

In the present invention, the status message received through the Tx / Rx transceiver 107 and the MAC 106 of the network connection unit 105 in the terminal device 101 is analyzed through the data processing unit 104, and the sleep mode controller 103. ) Determines whether the ONU is in sleep mode.

When the ONU is in the sleep mode, the Tx unit 109 of the terminal device 101 enters the sleep mode, and remains in the sleep mode until receiving the downlink traffic from the ONU 110 at any listening interval. do.

When the terminal device 101 receives the downlink traffic from the ONU 110 at a listening interval, the Tx unit 109 enters an activation state and remains active until a status message is received from the ONU 110. .

2 is a flowchart illustrating a sleep mode operation method of a terminal device in an EPON system according to an embodiment of the present invention.

Referring to FIG. 2, when the terminal device 101 receives a status message from the ONU 110 including status information of the ONU in an active state (S201 and S203), the terminal device 101 analyzes the status message to analyze the ONU 110. It is checked whether or not the sleep mode (S205).

If the ONU 110 is in the sleep mode, the terminal device 101 switches to the sleep mode, which is a mode for deactivating an internal component that transmits a signal (S207). In step S207, the terminal device 101 deactivates the Tx unit 109 to enter the sleep mode.

Next, the terminal device 101 maintains the sleep mode until receiving downlink traffic from the ONU 110 in the sleep mode state.

When the terminal device 101 receives the downlink traffic from the ONU 110 in the sleep mode state (S209), the terminal device 101 switches back to the activated state (S201).

3 is a message flow and state diagram between an ONU and a terminal device according to an embodiment of the present invention.

Referring to FIG. 3, upon receiving a status message from the ONU 110, the terminal device 101 enters a sleep mode. That is, the terminal device 101 also enters the sleep mode according to the sleep mode of the ONU 110, so that the sleep mode period is synchronized between the ONU 110 and the terminal device 101. The sleep period and the listening period are repeated, and the terminal device 101 maintains a sleep mode state.

When the ONU 110 is activated at some point in time, downlink traffic is generated from the ONU 110 in a listening period of the terminal device 101, and the terminal device 101 is switched to an activated state. . Thereafter, the terminal device 101 remains activated until the ONU 110 enters the sleep mode and sends a status message to the terminal device 101.

While the present invention has been described with reference to several preferred embodiments, these embodiments are illustrative and not restrictive. It will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit of the invention and the scope of the appended claims.

101 Terminal 102 Main Processor
103 Sleep Mode Control Unit 104 Data Processing Unit
105 Network Connection 106 MAC
107 Tx / Rx Transceiver 108 Tx
109 Rx section 110 ONU

Claims (5)

A terminal device receiving a service interface from an optical network unit (ONU) in an Ethernet-based passive optical network (EPON) system and implementing a sleep mode,
A network connection in communication with the ONU, receiving downlink traffic from the ONU, transmitting uplink traffic to the ONU, and receiving a status message including status information of the ONU; And
Analyzing the status message received by the network connection unit, if the state of the ONU is a sleep mode (sleep mode) state, it is switched to the sleep mode which is a mode for deactivating the internal component transmitting a signal in the active (Active) state And a main processor configured to switch back to an activated state upon receiving downlink traffic from the ONU in a state of being switched to a sleep mode.
The method of claim 1,
The network connection portion,
A Tx / Rx transceiver comprising an Rx unit for receiving downlink traffic from the ONU and a Tx unit for transmitting uplink traffic to the ONU; And
Terminal device comprising a MAC to perform operations in the MAC layer (Media Access Control layer) area in the OSI 7 layer.
3. The method of claim 2,
The main processor,
A sleep mode controller configured to analyze the state message and control to switch to a sleep mode by deactivating the Tx unit if it is determined that the ONU is in a sleep mode state; And
And a data processing unit performing a packet processing operation of at least three layers in an OSI 7 layer and performing a packet transmission / reception operation in association with the MAC and the Tx / Rx transceiver.
In a sleep mode operation method of a terminal device provided with a service interface from an optical network unit (ONU) in an Ethernet-based passive optical network (EPON) system,
When the terminal device receives a status message including status information of the ONU from the ONU in an active state, analyzing the status message to determine whether the ONU is in a sleep mode; And
And if the ONU is in a sleep mode, the terminal device transitions to a sleep mode which is a mode for deactivating an internal component transmitting a signal.
5. The method of claim 4,
And when the terminal device receives downlink traffic from the ONU in the sleep mode state, switching to the active state again.

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