One or more example embodiments relate to passive optical networks and ranging of optical network units.
Conventionally, a Passive Optic Network (PON) requires an extended period of quiet time on the fiber optic cable in order for an Optical Line Terminal (OLT) to discover and range a new Optical Network Unit (ONU). The quiet time is a period where no traffic from any known ONU can transmit data. This quiet time impacts overall bandwidth for the PON system. Also, if the PON system hosts dedicated time critical low latency traffic, it is not possible to disturb the traffic in order to have a sufficient quiet time to discover the new ONU using the convention methods.
One or more example embodiments relate to a method for a first optical transceiver to range one of a plurality of second optical transceivers.
In an example embodiment the method may include broadcasting a first ranging grant including a delay request to unranged second optical transceivers among the plurality of second optical transceivers. The delay request may indicate a first delay before the unranged second optical transceivers respond to the first ranging grant such that the unranged second optical transceivers respond after a desired delay. The method may also include determining whether a runt response is received in a quiet window established by the first optical transceiver. The quiet window may be a time when no responses are expected from ranged second optical transceivers among the plurality of second optical transceivers. The method may also include changing one of the desired delay or a timing of the quiet window in response to determining that no runt response was received in the quiet window, repeating the broadcasting and the determining in response to determining that no runt response was received in the quiet window. The method may also include identifying one of the unranged second optical transceivers in response to determining that a runt response was received, and establishing a ranged state with the identified unranged second optical transceiver.
In another example embodiment the method may include receiving a first ranging grant including a delay request at an optical transceiver, the delay request indicating a first delay before the optical transceiver responds to the first ranging grant such that the optical transceiver responds after a desired delay, determining the desired delay based on the delay request, sending a runt response after the desired delay with a laser of the optical transceiver, the runt response being sent with a laser power of the laser being below the maximum laser power such that the runt request does not substantially interfere with communication with other optical transceivers, receiving, from a network transceiver, a second ranging grant including an additional condition for response based on an identifier of the optical transceiver, sending the runt response in response to the identifier meeting the additional condition and establishing a ranged state with the network transceiver.
In another example embodiment the first optical transceiver may include a memory including computer readable instructions and a processor configured to execute the computer readable instructions. The memory, the processor and the computer readable instructions may cause the first optical transceiver to, broadcast a first ranging grant including a delay request to unranged second optical transceivers among a plurality of second optical transceivers, the delay request indicating a first delay before the unranged second optical transceivers respond to the first ranging grant such that the unranged second optical transceivers respond after a desired delay, determine whether a runt response is received in a quiet window established by the first optical transceiver, the quiet window being a time when no responses are expected from ranged second optical transceivers among the plurality of second optical transceivers, change one of the desired delay or a timing of the quiet window in response to determining that no runt response was received in the quiet window, repeat the broadcasting and the determining in response to determining that no runt response was received in the quiet window, identify one of the unranged second optical transceivers in response to determining that a runt response was received, and establish a ranged state with the identified unranged second optical transceiver.
In another example embodiment, an optical transceiver may include a memory including computer readable instructions and a processor configured to execute the computer readable instructions. The memory, the processor and the computer readable instructions may cause the optical transceiver to, receive a first ranging grant including a delay request at an optical transceiver, the delay request indicating a first delay before the optical transceiver responds to the first ranging grant such that the optical transceiver responds after a desired delay, determine the desired delay based on the delay request, sending a runt response after the desired delay with a laser of the optical transceiver, the runt response being sent with a laser power of the laser being below a normal laser power such that the runt response does not substantially interfere with communication with other optical transceivers, receive a second ranging grant including an additional condition for response based on an identifier of the optical transceiver, sending the runt response in response to the identifier meeting the additional condition, and establish a ranged state with the network transceiver.
Example embodiments will become more fully understood from the detailed description given herein below and the accompanying drawings, wherein like elements are represented by like reference numerals, which are given by way of illustration only and thus are not limiting of this disclosure.
Various example embodiments will now be described more fully with reference to the accompanying drawings in which some example embodiments are shown.
Detailed illustrative embodiments are disclosed herein. However, specific structural and functional details disclosed herein are merely representative for purposes of describing example embodiments. The example embodiments may, however, be embodied in many alternate forms and should not be construed as limited to only the embodiments set forth herein.
Accordingly, it should be understood, however, that there is no intent to limit example embodiments to the particular forms disclosed. On the contrary, example embodiments are to cover all modifications, equivalents, and alternatives falling within the scope of this disclosure. Like numbers refer to like elements throughout the description of the Figures.
In an example embodiment the ONU 310 may be ranged and the ONUs 320 and 330 may not be ranged. A ranged ONU such as ONU 310 may already have an assigned equalization delay. The equalization delay is calculated such that the time of flight of a request sent to the ONU 310, the standard response time (known to both the ONU 310 and the OLT 200), the equalization delay, and the time of flight for a response to the OLT 200 will add up to an expected delay. In some example embodiments, a communication frame may be 125 μs. Thus, the equalization delay allows the ranged ONU 310 and the OLT 200 to synchronize communication.
The flight times may depend on the length of fiber optic cable between the OLT 200 and the ONU 310. Thus, ranged ONUs at different distances from the OLT 200 may be assigned different equalization delays. The flight times and the response time may remain constant.
The OLT 200 may also include a start time in the request. The start time indicates a delay from the beginning of a communication frame when the OLT 200 expects to receive the response from the ONU 310. The ONU 310 may delay responding to the request by the start time so that the response arrives at the expected time.
For example, the OLT 200 may send a request at the start of a Downstream Physical (DS PHY) frame. The request may include a start time. The ONU 310 may receive the request from the OLT 200 after a flight time. After a standard response time, the ONU 310 may delay responding for the equalization delay and also for the start time. The ONU 310 may then respond to the request such that after a flight time the response arrives at an expected time at the OLT 200.
The laser may optionally have a laser power control circuit 357 that controls the power output of the laser.
In order to emulate the standard format for communicating with ranged ONUs, the OLT 200 may broadcast a pre-equalization delay for communication with unranged ONUs such as ONUs 320 and 330. The timing of the response depends on the distance of the unranged ONUs 320 and 330 from the OLT 200. Accordingly, the pre-equalization delay may represent a guess of how far away one of the unranged ONUs 320 and 330 is from the OLT 200.
After the OLT 200 has broadcast a pre-equalization delay for communication with unranged ONUs, the OLT 200 may send a first ranging grant at the start of the DS PHY frame from the perspective of the OLT 200. The first ranging grant may request a short low power response, known hereafter as a runt response RR from the unranged ONUs. The first ranging grant may arrive at the ONU 330 after a time of flight Tdni. The time of flight Tdni may depend on the length of fiber optic cable between the OLT 200 and the ONU 330. After a response time RspTimei the ONU may wait to send a response based on the pre-equalization delay Pre-Eqdi previously broadcast to unranged ONUs such as ONU 330. The ONU 330 may also wait for a random delay time Tran specific to the ONU. ONU 330 may then wait for an additional time StartTimei sent in the first ranging grant before responding with a runt response RR. The additional time StartTimei may be an example of a requested delay. The runt response RR may then arrive at the OLT 200 after a flight time Tupi. The flight time Tupi may depend on the length of the fiber optic cable 110 between the ONU 330 and the OLT 200 and thus may be the same as the flight time Tdni. The runt response RR may have a duration TDRR of about 40 ns or less. With a response of this length two unranged ONUs would have to have fiber optic cables with a difference in lengths of about 4 meters or less for two runt responses RR to interfere with each other. In order to prevent this interference, randomization can be used. Randomization may be accomplished by the OLT 200 requesting that each unranged ONUs change its random delay time Tran. This may create an offset between two unranged ONUs with interfering runt responses RR.
The OLT 200 may create a small quiet window when no response is expected from the ranged ONUs such as ONU 310. The small quiet window may be an example of a quiet window. The OLT 200 may create this window by not requesting responses from the ranged ONUs with start times that would cause the responses to arrive during the small quiet window. The small quiet window may exist for a time Tsqw that is a small fraction of the upstream frame size. For example, Tsqw may be about 500 ns or less. This provides a distinct advantage over the standard practice of quiet windows which are several frames long.
The timing delay Tdelay is the total time from the start of the OLT 200 beginning to send the first ranging grant to the start of the small quiet window. A response delay TRD may be the total of the time of flight Tdni, response time RspTimei, pre-equalization delay Pre-Eqdi, Tran, time StartTimei, and flight time Tupi added together. If TRd is between the timing delay Tdelay and the Timing delay plus the duration of the small timing window Tsqw minus the duration of the runt response TDRR such that the below equation is satisfied, the OLT 200 may be able to recognize the runt response in the small quiet window.
Tdelay≤TRD≤Tdelay+Tsqw−TDRR Equation 1:
If the runt response is not received in the small quiet window, the OLT 200 may adjust one or both of the timing delay Tdelay and the response delay TRD.
The timing delay Tdelay may be changed by moving the small quiet window to a different location in the communication window. This may be accomplished by the OLT 200 not requesting responses from ranged ONUs during a different portion of the communication window.
The time of flight Tdni, response time RspTimei, and flight time Tupi may be fixed. Accordingly, the TRD may be changed by the OLT 200 by broadcasting a new pre-equalization delay Pre-Eqdii for communication with unranged ONUs and/or by sending a new first ranging grant with a new time StartTimeii.
The OLT 200 may measure the time after the start of the small quiet window when the runt response is detected TRR.
A pre-equalization delay does not need to be used or a Pre-Eqdi of 0 μs may be used. Accordingly, the communications between the OLT 200 and the unranged ONUs 320 and 330 do not need to emulate the communications between the OLT 200 and the ranged ONU 310. However, it may be advantageous in some circumstances to use a pre-equalization delay Pre-Eqdi of 0 μs rather than using no pre-equalization delay so that separate programming is not needed for the ONUs to communicate while unranged and ranged.
At S525, the OLT 200 determines if a runt response was received in the small quiet window. If the OLT 200 determines that no runt response was received during the small quiet window, then the OLT 200 may adjust one of the response delay TRD or the timing delay Tdelay as disclosed above. Then the OLT 200 may repeat operation S505 if the pre-equalization delay is changed and repeat operation S510. The ONUs 320 and 330 may then repeat operations S515 and S520. The runt response may be recognized by any method that is well known in the art or by the method disclosed in U.S. application Ser. No. 15/606,094 which is incorporated by reference in its entirety, and attached in Appendix A.
If the OLT 200 determines that a runt response was received, optionally, at S528, the OLT 200 may broadcast instructions for unranged ONUs to send identifier information via subsequent runt responses RR in response to subsequent ranging grants.
If the OLT 200 determines that a runt response was received, at S530, the OLT 200 may broadcast a second ranging grant to the unranged ONUs with the same response time StartTime, random delay time Tran, pre-equalization delay, and total delay Tdelay as used in the first ranging grant that resulted in the runt response RR being received in small quiet window. The second ranging grant may include an additional condition for a response to be sent. The additional condition may be based on the identifier of the responding unranged ONU. For example, the additional condition may be that an unranged ONU respond with a runt response RR if the identifier of the ONU is a certain value, or contains a certain value at a given location in the identifier. The OLT 200 may also adjust the total delay Tdelay and/or response delay TRD based on a time within the small quiet window that the runt response RR was received TRR. The identifier may be a serial number or other unique identifier of the ONU.
At S535, the ONU 320 may respond to the second ranging grant with a runt response RRi if ONU 320 determines that the identifier of the ONU 320 meets the additional condition. At S540, the ONU 330 may respond to the second ranging grant with a runt response RRii, if ONU 330 determines that the identifier of the ONU 330 meets the additional condition.
At S545, the OLT 200 may determine if a runt response is received in the quiet window and if a unique identifier has been determined. If the OLT 200 determines that a unique identifier has not been determined the OLT 200 may broadcast a new second ranging grant with a new additional condition. Accordingly steps S530-S45 may be repeated until the OLT 200 determines that a unique identifier has been determined. If a unique identifier has been determined, the OLT 200 may record the identifier in the memory 220.
In some example embodiments the OLT 200, at S528, may broadcast instructions for the ONU to respond to a certain number of ranging grants with runt responses in accordance to the bits of the identifier of the ONU. For example, the instructions may instruct the ONU to respond to 8 different ranging grants with the last 8 bits of the identifier of the unranged ONU. Then the OLT 200 and ONU may repeat S530 and S535 8 times. The unranged ONUs may respond with a runt response to indicate a “1” or not respond to indicate a “0.” The OLT 200 may then determine using the received runt responses a determined portion of the identifier. Then the OLT 200 may repeat step S530 with the additional condition that the unranged ONU respond if the last 8 bits of the identifier are the determined portion of the identifier. If a runt response is received the OLT 200 may determine that the determined portion of the identifier is correct for at least one of the unranged ONUs. Or, if the determined portion is the entire identifier the OLT 200 may determine that the unique identifier has been determined. If a runt response is not received the OLT 200 may determine that there is interference and that it is not possible to obtain a unique identifier. Then the ONT 200 may broadcast instruction for each of the unranged ONUs to change the random delay times Tran and the OLT may repeat S528-S540.
In some other example embodiments the OLT 200 may determine a unique identifier of one of the unranged ONUs by consecutively sending second ranging grants with additional conditions that incrementally determine the individual bits of the identifier of the unranged ONU. The OLT 200, at S530, may broadcast a second ranging grant with an additional condition that an unranged ONU respond if the first digit of the identifier of the ONU is a “1.” At S545, the OLT 200 may determine if a runt response is received in the small quiet window. If a runt response is received in the small quiet window the ONU may determine that an unranged ONU has an identifier beginning with “1.” If no runt response is received in the small quiet window the OLT 200 may deter mine that the unranged ONU has an identifier beginning with “0.” At S545, based on the number of digits known to be included in ONU identifiers, the OLT 200 may determine if the number of determined digits of the identifier represents a complete unique identifier of the ONU. If the OLT 200 determines that a complete unique identifier has not been determined then the OLT 200 may repeat S530 with an additional condition including the determined bits and a condition for the next unknown bit. For example, if the runt response was received and the OLT 200 determines that the first bit of the identifier of the unranged ONU is “1,” the OLT 200 may send a second ranging grant with a condition that an unranged ONU only respond if the first two bits of the identifier are “11.” Conversely, if the runt response was not received in the small quiet window and the OLT 200 determines that the first bit of the identifier of the unranged ONU is “0” the OLT 200 may send a second ranging grant with a condition that an unranged ONU only respond if the first two bits of the identifier are “01.” Using the same operations the OLT 200 may determine the second bit of the identifier. The same operations can be used to determine each of the bits of the identifier of one of the unranged ONUs until the OLT 200 determines that the complete unique identifier has been determined.
The OLT 200 may repeat step S530 at certain intervals with the additional condition that the unranged ONU respond if the identifier includes the determined portion of the identifier. If a runt response is received the OLT 200 may determine that the determined portion of the identifier is correct for at least one of the unranged ONUs. Or, if the determined portion is the entire identifier the OLT 200 may determine that the unique identifier has been determined. If a runt response is not received the OLT 200 may determine that there is interference and that it is not possible to obtain a unique identifier. Then the ONT 200 may broadcast instruction for each of the unranged ONUs to change the random delay time Tran and the OLT 200 may repeat S528-540.
In other example embodiments the OLT 200 may determine the identifier of one of the unranged ONUs is by sending a second ranging grant with an additional condition based on a hash of the identifier of the unranged ONU. In some example embodiments an 8 bit hash function may be used. The same processes discussed above may be used to determine the individual bits of the hash of the identifier of one of the unranged ONUs. Then once the hash of the identifier of one of the unranged ONUs is determined the OLT 200 may determine each of the possible unique identifiers that result in the determined hash of the identifier of one of the unranged ONUs. Then the OLT 200 may incrementally determine the unique identifier of one of the unranged ONUs by sending a second ranging grants with the additional condition of one of the possible identifiers based on the hash of the identifier until a runt response is received in the quiet window indicating that the possible identifier is the identifier of one of the unranged ONUs.
After the OLT 200 determines, at S545, that a unique identifier has been determined, the OLT 200, at S550, may establish a ranged state with the identified ONU. For example, if the identifier for the ONU 330 is determined, then the OLT 200 may establish a ranged state with ONU 330. Establishing a ranged state may include assigning an equalization delay to the ONU 330 based on the identifier of the ONU 330.
At S640, the processor 230 may determine whether a runt response RR is received at the OLT 200 during the small quiet window based on signals received by the transceiver 240. If the processor 230 determines that no runt response has been received in the small quiet window, at S645, The OLT 200 may change at least one of the response delay TRD and the timing delay Tdelay as disclosed above using the processor 230 and the transceiver 240. The OLT 200 may repeat some or all of operations S610-S640 until the processor 230 determines a runt response RR is received. The processor may also determine whether a runt response was received during quiet periods, where no signal is received from the ranged ONUs, other than the small quiet window. If the processor determines that a runt response is received in a quiet period other than the small quiet window the processor may adjust the timing delay Tdelay based to the time when the runt response was received.
At S650, the OLT 200 may identify one of the unranged ONUs in response to the processor 230 determining at S640 that a runt response RR was received. The OLT 200 may identify one of the unranged ONUs using the processor 230, the transceiver 240 and the memory 220. Optionally, the processor 230 via the MAC 250 may control the transceiver 240 to broadcast instructions for unranged ONUs to send identifier information via subsequent runt responses RR in response to subsequent ranging grants. The processor 230, via the MAC 250, may cause the transceiver 240 to broadcast a second ranging grant with an additional condition for response based on an identifier of the optical transceiver. The processor 230 may determine if a runt response is received in the small quiet window and determine if a unique identifier has been determined. If the processor 230 determines that a unique identifier is determined then the processor may record the identifier in the memory 220, or in other words, cause the memory 220 to store the identifier. If the processor 230 determines that a unique identifier is not determined then the processor 230, via the MAC 250, may cause the transceiver 240 to broadcast a new second ranging grant with a new additional condition to the unranged ONUs.
The processor 230 of the OLT 200 may determine that the unique identifier is not obtainable by requesting that an unranged ONU respond with a runt response RR if the identifier of the ONU is the determined identifier or includes a determined portion of the identifier. If the processor 230 via the transceiver 240 determines that no runt response RR is received in the small quiet window, the processor 230 may determine that the unique identifier is not obtainable. If a unique identifier is not obtainable, the cause may be interference between at least two unranged ONUs. If the processor 230 determines that the unique identifier is not obtainable, the processor 230, via the MAC 250, may cause the transceiver 240 to broadcast instructions for all unranged ONUs to change the random delay time Tran of the ONU and repeat S640.
At S660, the OLT 200 may establish a ranged state with the identified unranged ONU. The OLT 200 may establish the ranged state with the identified unranged ONU using the processor 230, memory 220 and transceiver 240. The processor 230 may determine an equalization delay for the identified ONU based on any of or a combination of the timing delay Tdelay, the pre-equalization delay Pre-Eqdi, the response delay TRD, the time within the small quiet window that the runt response RR was received TRR, and a response delay for receiving the identifier after broadcasting the request for the unranged ONUs to send an identifier. The processor 230, via the MAC 250, may cause the transceiver 240 to send the equalization delay to the identified ONU. Once the ranged state is established, the ONU can respond to normal grants with normal (non runt) bursts without collision with normal bursts from other ranged ONUs.
At S710, the transceiver 350 may receive a pre-equalization delay Pre-Eqdi from the OLT 200. At S720, the transceiver 350 may receive a first ranging grant from OLT 200 including a time Start Time. At S730, the processor 360 may cause the ONU to wait to respond until after each of the Response time RspTimei, the pre-equalization delay Pre-Eqdi, and the time StartTimei have passed before sending a response. At S740, the processor 360, via the MAC 380, may cause the transceiver 350 to respond to the first ranging grant by sending a runt response RR at a low power of the laser 355, the low power being lower than normal power for sending data packets.
The processor 360 may cause the runt response RR to be sent at a low power of the laser by causing the transceiver to power up the laser 355 and before the laser 355 can power up to a normal power for transmitting data packets causing the transceiver to send the runt response. The processor 360 may also cause the runt response RR to be sent at a low power of the laser by causing the transceiver to restrict the power of the laser to a low power using the laser power control circuit 357.
Optionally, at S745, processor 360 via the transceiver 350 may receive instructions for a sending identifier information via subsequent runt responses RR in response to subsequent ranging grants.
At S750, the transceiver 350 may receive a second ranging grant with the additional condition based on the identifier of the ONU 330. The processor 360, via the MAC 380, may cause the transceiver 350 to send a runt response if the processor 360 determines that the identifier of ONU 330 meets the additional condition. The processor 360, at S760, via the MAC 380, may cause the transceiver 350 to send runt response after each of the Response time RspTimei, the pre-equalization delay Pre-Eqdi, and the time StartTimei to have passed. If the processor 360 determines that the identifier of ONU 330 does not meet the additional condition then the processor 360, via the MAC 380, may not cause the transceiver 350 to send the runt response.
At S770, the transceiver 350 may receive at least one communication from OLT 200 establishing a ranged state with ONU 330. The at least one communication may include an equalization delay for the ONU 330 to use in further communications with the OLT 200. These operations may be repeated or performed in a different order than the order shown in
The laser 355 does not need to send usable data when it is being controlled to send a runt response. When the laser is being controlled by the processor 340 to send the runt response the laser sends the runt response RR at a runt response operating level which is below the digital ‘1’ level. The runt response RR may be sent at a power level above the digital ‘0’ level.
In an example embodiment, the runt response RR may be sent during Ton at a time when the power is low enough that the runt response RR will not substantially interfere with communications between the OLT 200 and ranged ONUs. Substantial interference may be interference that cannot be corrected by forward error correction methods that are known and implemented in the art.
The processor 360 may control powering up or powering down the laser 355 such that the runt response RR can be sent during a portion of Ton when the runt response RR will not substantially interfere with communications between the OLT 200 and ranged ONUs. In an example embodiment, the runt response RR may be 96 bits sent at a rate of 2.48832 Gbps (about 38.4 ns), Ton and Toff, may be about 128 ns. Ton time may vary depending on the laser that is used. The runt response RR may be sent during Ton when the laser 355 reaches a power of sufficiently below normal power levels so as to not cause substantially impacting traffic of ranged ONUs. The runt response may be received at a power level below the sensitivity point of transceiver 230 of the OLT 200, because the runt response RR may not carry any data other than if the runt response RR is present or not. Sensitivity is the point where the transceiver 240 of the OLT 200 is no longer able to properly determine a “1” or “0” to a recoverable bit error level.
In another example embodiment, the laser power control circuit 357 may restrict the power of the laser to a power level below a normal power level for sending a digital “1.” In another example embodiment, the laser power control circuit 357 may restrict the power of the laser to a power level below a normal power level for sending a digital “0.”
The max input power at the receiver is the maximum power for the transceiver 240 of the OLT 200. The minimum input power at the receiver is the sensitivity of the transceiver 240 of the OLT 200. The runt response RR may be received with a power level above or below the sensitivity of the transceiver 240 of the OLT 200.
The above described example embodiments may provide the advantage that the PON may identify and range unranged ONUs without needing a large quiet window of multiple frames, thus the above described example embodiments may allow the PON to identify and range unranged ONUs without substantially impacting traffic of ranged ONUs.
Benefits, other advantages, and solutions to problems have been described above with regard to specific embodiments of the invention. However, the benefits, advantages, solutions to problems, and any element(s) that may cause or result in such benefits, advantages, or solutions, or cause such benefits, advantages, or solutions to become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims.