JP4903276B2 - Power saving in IEEE 802 standard network - Google Patents

Description

      The present invention relates to the field of communication networks, and more particularly to a system and method for performing power savings in IEEE 802 and ITU-TG.984 standard networks.

      The technology of the present invention and the requirements used therein are based on the IEEE 802 standard and the ITU-TG.984 standard. Increasing energy costs, larger data centers and higher electronic density are one of the reasons why companies are increasingly sensitive to the effects of energy consumption. In fact, many companies review the power consumption of the system in IT technology and decide whether or not energy costs can be reduced. One form of power consumption is energy consumption by communication equipment.

      The IEEE 802 standard network (including the ITU-TG.984 standard network in this specification) is a common choice for both enterprise and the first mile of access communications. An example of an IEEE 802 standard network is an Ethernet network standard. These are implemented with 100Base-T, 10GBASE-R and EPON standards. The importance of power saving in IEEE 802 standard networks has been reported by the IEEE 802.3 Working Group. The working group recently launched the Energy-Efficient Ethernet EEE Task Force (official name 802.3az) to determine how to reduce the average power consumption of telecommunications Ethernet. Various solutions have been proposed in the past.

US Patent Application No. 60 / 172,986 US Patent Application Publication No. 20090204828 US Patent Application Publication No. 2008034519 US Patent Application Publication No. 20090119524

      Patent Document 1 teaches a method of controlling power in a communication device by stopping or starting a clock signal between a MAC control logic module and a frame processor module.

U.S. Patent No. 6,057,032 teaches a hybrid approach that manages multiple low power modes in combination. This hybrid approach uses a combination of low-power idle technology and physical interface technology to selectively activate them within the communication device. In the physical interface technology, the link uses a high data rate (transmission rate) when data transmission needs are high, and a low data transmission rate when data transmission may be low.
In low power idle technology, the link sender can enter a low power idle mode, where the physical interface and energy on the link is disconnected (turned off) when there is no data transmission. That is, the sleep mode is entered. The sending physical interface does not turn off completely, but sends a refresh signal, allowing the receiver to keep the link synchronized and receive a prior notice to wake up from the low power mode.

      Patent Document 3 provides a function of reducing the power consumed by a group of Ethernet links when they are organized by Link Aggregated Groups. When the server or switch detects low bandwidth usage of multiple links in the group, it negotiates to move unnecessary links to a low power state. As bandwidth demands increase, the algorithm quickly reestablishes the link and distributes Ethernet traffic across multiple links as needed.

      Patent Document 4 discloses an Ethernet controller that operates in an active power state so that data packets can be transmitted and received at the maximum available link speed. When data packets are sent and received, the Ethernet controller operates in an idle power state, reducing energy consumption. The “idle power state” of Patent Document 4 is defined as a power state that is sufficient to maintain an open link with a link partner, but is insufficient to transmit and receive data. In other words, the “idle power state” maintains the Ethernet communication link between the Ethernet controller and the link partner.

      In this specification, a user communication device called a user device is a device placed on the user's premises, and provides an interface for transmitting and receiving data to and from a communication network related to the user. A network communication device called a network device is a device arranged in the center for a plurality of users, and is connected to the user device by a communication network to provide an interface for transmitting and receiving with a related communication network. The network device provides communication between user devices on the communication network or communication between the user device and another network.

      Conventional solutions for power saving in Ethernet networks have been directed to changing the link data rate and selectively reducing the power consumption of the physical interface of the user equipment. Using a lower data rate to transmit data is more power saving than using a higher data rate, but still uses power even if you keep transmitting at a lower data rate . In transmission over analog communications (eg, telecommunications Ethernet), the transmitter transmits at a lower power level to reduce power, but still uses power. By monitoring the idle transmission time in the user equipment and controlling the power by turning off the user equipment transmitter, the power of the transmitter can be saved, but the receiver continues to use the power. Various conventional low power and idle states can save transmitter and receiver power, but in the user equipment to initiate a communication channel for a “wake-up” signal from the network equipment. Still, power is consumed.

      An object of the present invention is to provide a system and method for performing power saving in a network. The target networks are not limited to Ethernet networks, but include IEEE802 standard networks and ITU-TG.984 standard networks. In the target network, the transmission medium does not facilitate the receiver to detect the signal from the transmitter (the signal that the transmitter has exited the low power state). It is a further object of the present invention to utilize information from user equipment and network equipment that initiates power saving by the user equipment.

In the IEEE 802 standard network and the ITU-TG.984 standard network, the system and method of the present invention for performing power saving from a user device and a network device to initiate power saving by the user device and the network device. Is used to perform power saving on the link, for example on an optical network, to break the limitations of the prior art.
The present invention provides a system and method for performing communication between a user device and a network device, whereby either the user device or the network device initiates a sleep mode for the user device. By executing the sleep mode in the user device, the transmitter and the receiver of the user device can be turned off for a predetermined time (sleep time). During this sleep time, the transmitter and receiver (also referred to as the physical interface of the device) do not consume power.

1 is a block diagram of a conventional IEEE802 standard network. A block diagram of a conventional EPON. The flowchart figure showing the sleep control message flow in the network of IEEE802 standard. A table representing the fields and octets in the SLEEP-REQ message. A table representing the fields and octets in the CHANGE-SLEEP-MODE message. A table representing the fields and octets in the SLEEP message. 1 is a block diagram of a system that performs power saving in a communication network. FIG.

The system and method of the present invention for performing power saving in an IEEE 802 standard network uses information from the user equipment and network equipment to initiate power saving by the user equipment and network equipment, for example on a link. Perform power saving on the optical network.
The present invention provides a system and method for performing communication between a user device and a network device, whereby either the user device or the network device initiates a sleep mode for the user device. By executing the sleep mode in the user device, the transmitter and receiver of the user device can be turned off for a predetermined time (sleep time). During this time, the transmitter and receiver (also referred to as the physical interface of the device) do not consume power.
In practice, depending on the configuration of the physical interface, there are components that cause floating or residual power consumption, and there is very little even during such measures if the power consumption of the physical interface is accurately measured. There is power consumption. However, such minimum power consumption is not considered relevant to the present invention.

      Unless otherwise noted, the term “transmitter” as used herein refers to a component of a device that transmits data to an associated communication network. The term “receiver” means a component of a device that can receive data from an associated communication network. The term “data” is used for all information communicated.

      One embodiment of the present invention performs power saving in an IEEE 802 standard network and is not limited to electrical or optical networks. Generally, a network device in an IEEE 802 standard network communicates with a plurality of user devices. Thus, the user device can enter sleep mode, but the network device is busy communicating with other user devices or other networks and has no idle time for the network device to enter sleep mode. So do other measures. Although this description of operation is for normal operating conditions, the method is not limited to being performed only on user equipment, and network devices can also enter sleep mode. A configuration example in which the network has only two devices (one network device and one user device) is an example useful for the network device to enter a sleep mode. If either of the two devices has no data to send to the other device, both devices can enter sleep mode.

      One embodiment of the present invention will be described using EPON. In this case, the user device is an optical network unit ONU (optical network unit), and the network device is. The optical line terminal is an OLT (optical line terminal), and the communication network is an EPON (Ethernet passive optical network) network.

      FIG. 1 shows an IEEE802 standard network. In the figure, a network device 100 is connected to user devices (102A, 102B, 102N) and provides communication among a plurality of user devices (102A, 102B, 102N) on the network. As an option, the network device 100 may provide communication between the user device (102A, 102B, 102N) and the other core network 106, for example via the network switch 104.

      Referring to FIG. 2, EPON represents an IEEE 802 standard network. In the figure, an OLT 200, which is a network device, is connected to ONU-1 202A, ONU-2 202B, and ONU-3 202N via a passive optical splitter 208, and provides communication between a plurality of user devices on the network. To do. As an option, the OLT 200 may be connected to, for example, the network switch 104 to provide communication between the user equipment and the other core network 106.

In FIG. 3, time 300 is shown as a relative scale progressing toward the bottom of the page. With this sleep control message flow, the transmitter and receiver of the device are powered down for a predetermined time (the transmitter and receiver do not consume power during this time), thereby realizing power saving of the device.
In the first case, the sleep control message flow starts when the network device 100 has no data to send to the user device 102A. The network device 100 sends a message (SLEEP-REQ: 302) to the user device 102A. This message requests the user equipment to transition to periodic sleep mode. If the user device 102A does not have data to transmit, the user device responds by sending a request to enter sleep mode (CHANGE-SLEEP-MODE 304A) to the network device 100 and moves to the periodic sleep mode 303A. .
In the second case, if the user device 102A does not have data to send, the sleep control message flow starts with the user device sending CHANGE-SLEEP-MODE 304A to the network device 100.

      In both cases, if the network device 100 does not have data to send to the user device 102A, the network device sends an instruction to the user device. This instruction instructs the user apparatus to sleep for a predetermined sleep time. This is SLEEP 306A. The network device 100 stops the keep-alive process and stops other communications to the user device 102A (308). When user device 102A receives the sleep instruction (306A), the user device transitions to sleep mode (310A) and powers down the appropriate components (usually transmission logic and receiver). When the predetermined sleep time for entering sleep is reached, the user device 102A transitions to the periodic sleep mode (303B) and powers up the appropriate elements (eg, transmitter and receiver). The user device prepares to receive a permission message (GATE message) from the network device. This permission message permits transmission of the user device. The network device 100 can know when the predetermined sleep time for the user device 102A has been reached, and sends a transmission opportunity message (GATE command 312A (permission message)) to the user device.

      If the user device 102A does not have data to be transmitted to the network device 100, the user device 102A sends a REPORT 314A. This indicates that the user device does not have data to transmit, and the user device 102A returns to sleep mode. When the network device 100 does not have data to be transmitted to the user device 102A, the network device 100 sends SLEEP 306B to the user device 102A. When user device 102A receives SLEEP instruction 306B, user device 102A transitions to sleep mode 310B. When the predetermined time to sleep is reached, the user apparatus 102A again enters the periodic sleep mode 303C, and the network apparatus 100 transmits GETE 312B.

      When the user apparatus 102A has data to be transmitted to the network apparatus 100, the user apparatus 102A transmits REPORT 314B. This REPORT 314B indicates that the user apparatus 102A desires transmission. The network device 100 sends the GATE 312C to the user device 102A, enables (activates) the keep-alive process, and executes other communication to the user device (316). User device 102A transmits a message indicating that user device 102A transitions from the periodic sleep mode to the normal mode. This is indicated as CHANGE-SLEEP-MODE 304B. The user apparatus 102A shifts from the periodic sleep mode to the normal mode normal mode (318). Communication is restored here as usual. If there is again no data to send, the sleep control message flow is repeated.

      If the network device receives the CHANGE-SLEEP-MODE 304 from the user device 102A and the network device has data to be transmitted to the user device, the network device sends the data to the user device as a normal data message. When the user equipment receives data without receiving the SLEEP indication 306, the user equipment transitions from the periodic sleep mode to the normal operating mode.

      In one embodiment of the present invention, the predetermined sleep time can be manually determined (configurable) by the system operator of the network device or user device. In another embodiment, the predetermined sleep time is calculated by the network device and sent to the user device as part of the sleep message. If the time is synchronized with the user device and the network device, the predetermined sleep time is an absolute time in the future. In one embodiment, if the current time is the first time stamp (F424 base16), the absolute predetermined sleep time is the second time stamp (605234 base16 = timestamp is 100 milliseconds). Stuff). In other embodiments, the predetermined sleep time is a relative time. In one embodiment, this relative predetermined sleep time may be a value of (BA2E8BA base16 = 100 milliseconds). In these discussions or specific applications, other methods of determining a predetermined sleep time will be apparent to those skilled in the art.

      In an optional embodiment, the network device 100 monitors the communication traffic load and determines that the load on the user device 102A is light, the network device sends a SLEEP_REQ 302 to the user device. In this embodiment, the user equipment has data to send but accepts SLEEP_REQ, transitions to periodic sleep mode, and sends CHANGE-SLEEP-MODE to the network equipment. This data is stored in the user equipment until the user equipment transitions to the normal mode, after which the data is transmitted with a relatively high load on the communication channel.

      In an optional embodiment, the network device first sends SLEEP to one user requesting CHANGE-SLEEP-MODE. Subsequent SLEEP messages are sent (broadcast) to all user devices on the network and to all user devices that are in periodic sleep mode and then transition to sleep mode.

      In an optional embodiment, CHANGE-SLEEP-MODE 304B is sent by the user equipment immediately after receiving GATE 312B. In another embodiment, the user equipment transmits user data immediately after receipt of GATE 312B. This indicates to the network device that the user device has shifted to the normal mode.

      The algorithm that determines to send SLEEP is not within the scope of the present invention. One embodiment is based on the network device's decision to send SLEEP upon receipt of SLEEP-REQ from the user device.

      In one embodiment, it is preferable to change the order of mode transition, message transmission, keep-alive process stop, and enable. In one embodiment of the invention, network device 100 stops 308 the keep-alive process and other communications, and then sends a SLEEP indication 306 to user device 102A. Other implementation methods will be apparent to those skilled in the art upon reference to the description herein.

      In order to perform the above method, the messages exchanged between the user equipment and the network equipment need to contain sufficient information to provide the control necessary for sleep control message flow (power saving control). In an IEEE 802 standard network, the use of a Media Access Control (MAC) layer is not sufficient to implement this control. Therefore, it is necessary to provide a mechanism for sufficiently controlling the sleep control message flow.

      One embodiment of a mechanism that provides control of the sleep control message flow uses the message format and state information of the network control layers (eg, 802.1 MAC client layer and 802.3 MAC control layer) on the MAC layer. This network control layer includes a mechanism for establishing time synchronization, and this shared time concept is used for control purposes. Extending the current time synchronization mechanism, the transmitter can send a special message to inform the receiver that the transmitter has not received data for a predetermined sleep time.

In EPON, the sleep control message flow is executed in a network control layer (multipoint MAC (MPCP) control layer) on the MAC used for controlling multiplexing. The current MPCP specification includes a mechanism that establishes time synchronization and uses this shared time concept (with a guard region) to allow multiplexed transmission. Extending the current MPCP time synchronization mechanism, the transmitter can send a special message to inform the receiver that the transmitter has not received data for a predetermined sleep time.
Furthermore, the MPCP layer is modified to stop the keep alive function while the user apparatus is in the sleep mode. The control handshake uses IEEE802 conventions, for example, one notification, which is symmetric to GPON using three notifications. In EPON, the above-described user device and network device are executed as ONU and OLT.

FIG. 4 is a table showing SLEEP-REQ message fields and octets. The field is based on a general MPCP frame format. This is known as an MPCP data unit (MPCPDU). All MPCPDUs are 64-byte MAC control frames and consist of the following fields:
Destination address (Destination address DA): The destination address field of the MAC control frame contains a 48-bit address of the destination device to which the frame is transmitted.
Source address SA: The source address field of the MAC control frame contains the 48-bit individual address of the device transmitting the frame.
Length / Type: The length / type field of the MAC control frame is a 2 octet field. This includes hexadecimal 88-08. This value is universally assigned to identify the MAC control frame.
The Opcode: Opcode field is a 2-octet field that identifies a specific MAC control frame.
The OUI: OUI field is a 3 octet configurable field.
Extended Opcode: Can be constructed. In the SLEEP-REQ embodiment, the value 00-00, (hexadecimal notation) is used to indicate that this frame is a SLEEP-REQ message.
Pad / Reserved: This field carries information related to a specific MPCP function. Part of the payload not used by the Opcode-specific field is filled with zeros.
Freme check sequence (FCS): Frame check sequence. This FCS field has a CRC-32 value. This is used by the MAC to authenticate the integrity of the received frame.

      FIG. 5 is a table showing fields and octets for the CHANGE-SLEEP-MODE message. This field is similar to that of SLEEP-REQ. The extended Opcode field is composed of the value 00-01 (hexadecimal), and indicates that this frame is a CHANGE-SLEEP-MODE message. Additional fields are identified. In one octet field of the new mode, the device is requesting a change from periodic sleep mode to normal mode (indicated by value 0) or from normal mode to periodic sleep mode (indicated by value 1) Indicates whether a change is requested.

      FIG. 6 is a table showing the execution of SLEEP message fields and octets. This field is similar to that of SLEEP-REQ. The extended Opcode field is constructed with the value 00-02 (hexadecimal) and is used to indicate that this frame is a SLEEP message. Additional fields are identified. Wake-up time: The 4-octet field indicates a predetermined sleep time. In EPON, this value is preferably the EPON clock, ie a time stamp based on time quanta (1 time quanta or 1 TQ = 16 nanoseconds).

      As described above, the specific fields, lengths, and values of control (power saving control) required for the sleep control message flow vary depending on the application. Other implementations of the control mechanism will be apparent to those skilled in the art from this specification.

      Referring to FIG. 7, the user device 702 includes a communication module 704 that communicates via a network, and a processing system 706 that is connected to the communication module 704. The processing system 706 has a processor 708. The processor 708 includes a sleep control module 710 that initiates a sleep control message flow, and a mode control module 712 that causes the user device to transition to a periodic sleep mode when the sleep control message flow is initiated. Connections between the modules are not shown in FIG.

      The network device 700 is connected to the user device 702. The network device 700 includes a communication module 730 that communicates via a network, and a processing system 732 that is connected to the communication module 730. The processing system 732 includes a processor 734. The processor 734 includes a sleep time determination module 736 that determines the sleep time that the user device is in sleep mode. User device 702 does not use power to communicate during communication with network device 700. The processor 734 includes a sleep time determination module 736. The sleep time determination module 736 determines whether the network device 700 transmits data to the user device 702, and executes transmission of a data message from the network device. If the network device 700 does not have data to send to the user device 702, the sleep time determination module 736 performs a sleep message transmission from the network device to the user device, and the network device is associated with the user device. Stop the keep alive process.

      The processing system 704 of the user device 702 includes a sleep determination submodule 714. The sleep determination submodule 714 causes the user device 702 to enter the normal mode when the user device 702 receives a data message from the network device 700 while the user device 702 is in the periodic sleep mode. Alternatively, when the user device receives a sleep message from the network device, the user device is shifted to the sleep mode for the sleep time.

      In one embodiment of the present invention, the sleep control module 710 of the user device 702 is activated to send a first modified sleep mode message from the user device 702 to the network device 700. In another embodiment, the processing system 732 of the network device 700 includes a network device sleep control module 738 and sends a sleep request message from the network device 700 to the user device 702 to initiate the sleep control message flow. Do.

      The above description relates to one embodiment of the present invention, and those skilled in the art can consider various modifications of the present invention, all of which are included in the technical scope of the present invention. The The numbers in parentheses described after the constituent elements of the claims correspond to the part numbers in the drawings, are attached for easy understanding of the invention, and are used for limiting the invention. Must not. In addition, the part numbers in the description and the claims are not necessarily the same even with the same number. This is for the reason described above. With respect to the term “or”, for example, “A or B” includes selecting “both A and B” as well as “A only” and “B only”. Unless stated otherwise, the number of devices or means may be singular or plural.

100 Network device 102 User device 104 Network switch 106 Core network 202 ONU
208 Splitter 200 OLT

FIG.
303A: Evaluate and transition to periodic sleep mode 303B: Transition to periodic sleep mode 303C: Transition to periodic sleep mode 310A: Transition to sleep mode 310B: Transition to sleep mode 318: Transition to normal mode 308: Stop keep alive 316: Enable keep alive

FIG.
Field octet destination address source address length / type = 88-08 16
OPCODE = FF-FE 16
OUI = <can be arranged>
Extended OPCODE = 00-00 16
PAD / Reservation 5
New mode Fig. 6
Wake-up time figure 7
700: Network device 702: User device 704, 730: Communication module 706, 732: Processing system 708, 734: Processor 710: Sleep control module 712: Mode control module 714: Sleep determination submodule 736: Sleep time determination module 736: Sleep Decision module 738: network

Claims (15)

In a method for power saving a communication network,
(A) starting a sleep control message flow between the user device and the network device;
(B) moving the user equipment to a periodic sleep mode;
(C) determining a sleep time during which the user apparatus is in a sleep mode;
In the sleep mode, the user device does not use power for communication with the network device,
(D) When the network device needs to transmit data to the user device,
(I) transmitting a data message from the network device;
(Ii) upon receiving the data message, the user equipment transitions to a normal mode;
(E) When the network device does not have data to be transmitted to the user device,
(I) transmitting a sleep message from the network device to the user device;
(Ii) the network device stops a keep-alive process associated with the user device;
(Iii) A method for saving power in a communication network, comprising: when the user device receives the sleep message, the user device transitions to a sleep mode for the sleep time. (F) moving the user equipment from the sleep mode to the periodic sleep mode based on the sleep time;
(G) transmitting a first permission message from the network device to the user device based on the sleep time;
This checks the operation of the user device,
(H) Upon receiving the first permission message, the user equipment transmits a first report message to the network equipment;
The first report message indicates that the user equipment has data to be transmitted;
(I) Upon receipt of the first report message, the network device
(I) enabling the keep-alive process associated with the user equipment;
(Ii) transmitting a second permission message from the network device to the user device;
(J) Upon receiving the second permission message at the user device, the user device
(I) transitioning from the periodic sleep mode to a normal mode;
(Ii) transmitting a second modified sleep mode message to the network device.
The method of claim 1 wherein: The method according to claim 1, wherein the step (A) starts by transmitting a first modified sleep mode message from the user device to the network device. The method according to claim 1, wherein the step (A) starts by transmitting a sleep request message from the network device to the user device. The method according to claim 4, wherein the step (A) is performed based on a communication traffic load. The method of claim 1, wherein step (C) is manually adjusted. The sleep time is transmitted from the network device to the user device.
The method of claim 1 wherein: The sleep time is included in the sleep message.
The method of claim 1 wherein: The step (i) of (E) is performed by broadcasting the sleep message to a plurality of user devices including the user device.
The method of claim 1 wherein: Upon receiving the first permission message, the user equipment sends a second report message to the network device;
The second report message indicates that there is no data to be transmitted by the user equipment;
(K) When the network device does not have data to be transmitted to the user device,
(I) transmitting a sleep message from the network device to the user device;
(Ii) when the user device receives the sleep message, the user device transitions to a sleep mode for the sleep time; and (L) the network device has data to be transmitted to the user device. Is
(I) transmitting a third permission message from the network device to the user device;
(Ii) enabling the network device to enable the keep-alive process associated with the user device;
(Iii) when the user device receives the third permission message, the user device transitions from a periodic sleep mode to a normal mode and transmits a second modified sleep mode message to the network device. The method according to claim 2. The method of claim 1, wherein the user device and the network device communicate via an IEEE 802 standard network. The user device is an EPON ONU;
The method of claim 1, wherein the network device is the EPON OLT. In a system that performs power saving in a communication network,
(A) a user device;
(B) a network device operably connected to the user device;
(C) a sleep determination submodule in the processing system of the user device;
Have
The user device (A)
(I) a communication module that communicates via a network;
(Ii) a processing system operatively connected to the communication module;
Have
The processing system includes a processor having the following modules (a) and (b):
(A) a sleep control module that initiates a sleep control message flow;
(B) After starting the sleep control message flow, a mode control module that shifts the user apparatus to a periodic sleep mode. The network apparatus (B)
(I) a communication module that communicates via a network;
(Ii) a processing system operably connected to the communication module;
Have
The processing system includes a processor including the following modules (a) and (b):
(A) a module for determining a sleep time during which the user apparatus is in a sleep mode;
The user device in the sleep mode does not use power for communication with the network device,
(B) a sleep determination module that determines:
(I) if the network device needs to send data to the user device, send a data message from the network device;
(Ii) If the network device does not have data to be transmitted to the user device,
(X) transmitting a sleep message from the network device to the user device;
(Y) the network device stops a keep alive process associated with the user device;
The sleep determination submodule (C), when the user equipment is in a periodic sleep mode,
(Z) When the user device receives the data message from the network device, the user device shifts to the normal mode,
(V) A system for performing power saving in a communication network, wherein when the user device receives the sleep message from the network device, the user device is shifted to a sleep mode during a sleep time. The system according to claim 13, wherein the sleep control module of the user device transmits a first change sleep mode message from the user device to the network device. The network device processing system includes a network device sleep control module;
The system according to claim 13, wherein the sleep control module of the network device starts a sleep control message flow by transmitting a sleep request message from the network device to the user device.

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