WO2012065097A1 - Method and apparatus for assigning wireless network packet resources to wireless terminals - Google Patents
Method and apparatus for assigning wireless network packet resources to wireless terminals Download PDFInfo
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- WO2012065097A1 WO2012065097A1 PCT/US2011/060427 US2011060427W WO2012065097A1 WO 2012065097 A1 WO2012065097 A1 WO 2012065097A1 US 2011060427 W US2011060427 W US 2011060427W WO 2012065097 A1 WO2012065097 A1 WO 2012065097A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W74/00—Wireless channel access
- H04W74/002—Transmission of channel access control information
- H04W74/006—Transmission of channel access control information in the downlink, i.e. towards the terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
Definitions
- Embodiments of the present invention relate generally to communication systems and more particularly to devices, systems, and methods providing and enabling assigning packet resources of a wireless network to plural wireless terminals.
- a wireless terminal requiring network resource will transmit a request for the network resource.
- Each wireless terminal requests service from the network by sending a channel request over an access channel.
- a channel request may be sent either to request circuit-switched service or to request packet switched service. If a wireless terminal requires packet service, it sends a so-called packet channel request.
- the network responds to a channel request by sending either an assignment message or an assignment reject message over an access grant channel.
- the assignment message indicates that a wireless terminal has been assigned a channel.
- the assignment reject message indicates that the wireless terminal has not been assigned a channel, and is sent when the network does not have enough resource to allocate the requested channel.
- Channels including the access channel are time-divided into data slots each containing a predetermined amount of data.
- a typical network can receive a channel request in every data slot of the access channel. However the network can only send an assignment message or assignment reject message on the access grant channel during a small fraction of the data slots of the access grant channel. Also, the network can only send an assignment message in response to one packet channel request at any one time, each assignment message addressing only one wireless terminal. Therefore the network can respond positively to only one packet channel request at a time during only a portion of the data slots of the access grant channel.
- the data slots of both the access channel and the access grant channel typically contain the same number of information bits.
- a consequence is that wireless terminals which have sent packet channel requests and do not receive any response from the network will send more packet channel requests.
- a wireless terminal Once a wireless terminal has transmitted a maximum number of packet channel requests, defined by the network via broadcast information, and has not received an assignment message in response, the wireless terminal will determine that an access channel failure has occurred and will trigger cell reselection.
- the cell reselection may require the wireless terminal to perform a registration update before it can send or receive user data. Registration updates use significant system resources and are time consuming. Multiple access channel failures can therefore lead to poorer system performance.
- MTC Machine Type Communication
- M2M Machine to Machine communication
- An example of a so-called MTC wireless terminal is a smart meter that automatically reports a measured reading to an MTC server on a regular basis, by transmitting a report comprising MTC data.
- Other examples of such devices are personal health monitors, vehicle/goods tracking devices, environmental monitors and security monitors.
- MTC wireless terminals For MTC applications it is possible to have very large number of MTC wireless terminals within a very small area, particularly in the same cell. Each MTC wireless terminal may need to communicate with the network on a frequent basis and this can lead to overloading of the network when there is transmission of a large number of packet channel requests in a given time. [0010]
- One possible solution is to increase the delay between adjacent channel requests from any given MTC wireless terminal but this only prolongs the problem. If the delay is too long then the MTC wireless terminal may have generated a new report while its previous report is still waiting to be sent. Hence this solution is not suitable for all cases.
- a transmitted single packet assignment message can be used by a network to enable packet assignment to be initiated for plural wireless terminals. This makes more efficient use of each such message when multiple packet channel requests are received by the network.
- the effective capacity of the channel via which the single packet assignment message is transmitted is at least doubled and may be tripled.
- the increased capacity acts to reduce congestion on the channel. This increases the probability of a wireless terminal receiving a positive response to a channel request which it sends. The probability of a subsequent successful data transfer is thereby increased.
- the claimed features may result in improved efficiency of the assignment procedure for both one-phase and two-phase data transfer on the uplink and the downlink.
- the features may also be applied to address the problem of a bottleneck that exists in the first phase of data transfer due to limited capacity of the channel used for indicating assignment of resource to wireless terminals.
- FIG. 1 is a schematic diagram of a wireless cellular communication system according to some embodiments of the present invention.
- FIG. 2 is a diagram illustrating a network apparatus and a wireless terminal in communication with each other over a wireless link according to some embodiments of the present invention.
- FIG. 3 is a more detailed schematic diagram of the network apparatus shown in FIG. 2 according to some embodiments of the present invention.
- FIG. 4 is a flow diagram of a process for assigning a packet channel to plural wireless terminals according to some embodiments of the present invention.
- FIG. 5 is a schematic diagram representing a network apparatus and a wireless terminal of a GERAN wireless communication system according to some embodiments of the present invention.
- FIG. 6 is a diagram illustrating an arrangement for a network apparatus to assign packet channels to plural wireless terminals according to some embodiments of the present invention.
- FIG. 1 is a schematic diagram of a wireless cellular communication system
- the wireless cellular communication system 100 includes a network 101 comprising base stations 110, 111, 114, base station controllers 141-144 and mobile switching centres 151, 152.
- the system 100 also includes wireless terminals 123-127 which are able to communicate with the base stations 110, 111, 114 via wireless links 160.
- Base stations 110, 111, 114 and wireless terminals 123-127 each have a transmitter and a receiver which are used to transmit and receive signals, respectively.
- a downlink signal is transmitted by a base station 110, 1 11, 114 of the network 101 and received by a wireless terminal 123-127.
- An uplink signal is transmitted by a wireless terminal 123-127 and received by a base station 110, 111, 114 of the network 101.
- the base station controllers 141-144 act to route signals carrying data to and from different wireless terminals 123-127 in the same cell or in different cells, under the control of the mobile switching centres 151, 152 via the base stations 110, 111 and 114.
- the mobile switching centres 151, 152 are connected to a public switched telephone network (PSTN) 162. Signals carrying data may be transferred between each of the wireless terminals 123-127 and communications equipment of other communications networks via the public switched telephone network 162.
- PSTN public switched telephone network
- communication systems include wired systems, fibre optic systems and other mobile cellular communication systems of different types and conforming to different standards.
- the wireless communication system 100 is designed so that a wireless terminal 123-127 can be registered to a selected base station (the wireless terminal's active base station) at any one time.
- the wireless terminal 123-127 can be registered to a different base station by a process known as cell reselection, so that the newly- assigned base station becomes the wireless terminal's active base station.
- Cell reselection is typically performed when a wireless terminal moves between cells, or when the quality of data sent between the active base station and the wireless terminal reduces below a threshold, or when a wireless terminal is denied a network resource which it requests, for example due to traffic congestion in the cell to which it is registered.
- Voice data is mostly transmitted using a circuit-switched connection, as is short message service (SMS) data.
- SMS short message service
- Voice data is sent with minimal delay (termed latency).
- Data such as documents, images and video are generally sent using a packet connection in which the data are divided into so-called packets which may be sent with variable delay or latency and may be sent intermittently.
- FIG. 2 is a simplified diagram illustrating a network apparatus 210 and a wireless terminal 220 in communication with each other over two wireless links comprising a downlink 230 and an uplink 240.
- a wireless terminal 220 is shown, there will typically be a multiple number of such wireless terminals 220 each capable of communicating with the network apparatus 210 within a given time period.
- a base station containing one or more network apparatus 210 typically has one or more antennas that can receive and transmit signals in multiple directions. Therefore signals sent on the downlink 230 and uplink 240 are typically transmitted in multiple directions. As a consequence, a signal transmitted by the network apparatus 210 may be received by plural wireless terminals.
- the functionality of network equipment varies between different networks such that base stations may have a variable degree of integration.
- the combined functions performed together by the BSC and the base station may be shared differently so that a more integrated base station may have functions that are commonly contained in a BSC.
- the network apparatus 210 in this example corresponds to either the base station 110 of FIG. 1 or the combination of base station controller 144 and base station 110 of FIG. 1, depending on what functionality is within the base station 110 of FIG. 1.
- the wireless terminal 220 corresponds to the wireless terminal 125 of FIG. 1.
- the signals sent on the downlink 230 and uplink 240 carry user data transmitted typically on a traffic channel, and control data transmitted on a control channel.
- 'User data' is data for use by, or for sending by, the wireless terminal 220 and may include packet data.
- the wireless terminal 220 comprises a receiver 221 for receiving data including user data and control data over the downlink 230.
- the wireless terminal 220 also includes a transmitter 222 which can transmit user data and control data on the uplink 240.
- the transmitter 222 and receiver 221 are controlled by processor 223 according to instructions and data e.g. resource parameters contained in a memory 224 coupled to the processor 223.
- the network apparatus 210 comprises a transmitter 211 for transmitting data including user data and control data via the downlink 230, and a receiver 212 for receiving user data and control data via the uplink 240.
- the transmitter 211 and receiver 212 are controlled by processor 213 according to instructions and data contained in a memory 214 coupled to the processor 213.
- Control data transmitted by the transmitter 211 of the network apparatus 210 and control data transmitted by the transmitter 222 of the wireless terminal 220 includes control data transmitted on one or more control channels.
- a number of wireless terminals 220 may require packet service of the network 101 for sending or receiving packet data.
- the wireless terminal 220 may transmit a request for a packet channel in the form of a packet channel request message.
- a packet channel request message is typically transmitted over a control channel.
- Control channels are commonly used in wireless communication systems for transmitting and receiving signaling information i.e. control data.
- control data is transmitted over a control channel by wireless terminals to request a packet channel.
- the receiver 212 of the network apparatus 210 receives the control data comprising the packet channel request message.
- the receiver 212 of the network apparatus 210 may also receive one or more other packet channel request messages transmitted by other wireless terminals (not shown in the figure).
- the receiver 212 receives a number, m, of packet channel requests transmitted by wireless terminals within a time period.
- the number m is a variable number, greater than or equal to zero, that depends on the number of wireless terminals within communication range of the network apparatus 210 that send packet channel requests in the time period.
- the number m also depends on the number of packet channel requests that the network apparatus 210 can receive in the time period. For example, if five wireless terminals send packet channel requests within the time period and the network apparatus 210 is able to receive up to 50 packet channel requests within the period, then m is equal to 5. Alternatively, if 100 wireless terminals send packet channel requests within the time period and the network apparatus 210 is able to receive up to 50 packet channel requests within the period, then m is equal to 50.
- the network 101 can respond to up to a number n of the received packet channel requests by assigning network resources to the n wireless terminals which transmitted the n packet channel requests and then transmitting an assignment message which indicates that resources have been assigned to the n wireless terminals.
- the number n therefore represents the number of packet channel assignments that the network apparatus will indicate within a packet assignment message.
- the number n is greater than or equal to zero and is less than or equal to the number m.
- the number n is determined by the available network resources and by the available bandwidth of the access grant channel which carries the packet assignment message.
- n has a maximum value that is significantly less than the maximum value of m. For example the maximum value of m may be around fifty and the maximum value of n may be four.
- the processor 213 of the network apparatus 210 responds to some or all of the m received packet channel request message by controlling the transmitter 211 of the network apparatus 210 to transmit either an assignment message or an assignment reject message over a control channel (access grant channel) used to assign a channel to wireless terminals.
- the assignment message indicates that the n wireless terminals have been assigned a packet channel.
- the assignment reject message indicates that the wireless terminal has not been assigned a packet channel, and is sent when the network does not have enough resource to allocate the requested packet channel.
- the receiver 221 of the wireless terminal 220 receives the assignment message or alternatively the assignment reject message.
- the processor 223 of the wireless terminal 220 responds according to the assignment message or assignment reject message.
- the processor 223 responds to an assignment message by controlling the transmitter 222 to transmit a signal using the assigned packet channel indicated by the assignment message.
- the processor 223 will respond to an assignment reject message by transmitting another packet channel request after a defined time interval.
- the processor 223 initiates a cell reselection.
- FIG. 3 is a more detailed schematic diagram of the network apparatus shown in FIG. 2.
- the processor 213 is shown as including various functional blocks for ease of understanding. The functions of those functional blocks may be all contained within the processor 213 or some or all of the functions may be outside the processor
- DSP digital signal processor
- the processor 213 in this example comprises an associator 313, an assignor 314 and a block scheduler 315.
- the receiver 212 receives a number, m, of packet channel requests transmitted by wireless terminals within a time period.
- the number m is a variable number, greater than or equal to zero, that depends on the number of wireless terminals within communication range of the network apparatus 210 that send packet channel requests in the time period.
- the number m also depends on the number of packet channel requests that the network apparatus 210 can receive in the time period. For example, if five wireless terminals send packet channel requests within the time period and the network apparatus 210 is able to receive up to 50 packet channel requests within the period, then m is equal to 5. Alternatively, if 100 wireless terminals send packet channel requests within the time period and the network apparatus 210 is able to receive up to 50 packet channel requests within the period, then m is equal to 50.
- the associator 313 is coupled to the receiver 212 and associates the received packet channel requests with the wireless terminals which transmitted the packet channel requests, by identifying temporary identifications contained in the packet channel requests.
- the temporary identifications comprise sets of random bits which the network 101 associates temporarily with the wireless terminals which transmitted the packet channel requests.
- the associator outputs the temporary identifications to the assignor 314.
- the assignor 314 assigns packet resources of the network to a group of n wireless terminals that include at least some of the m wireless terminals which transmitted the m packet channel requests.
- the number n represents the number of packet channel assignments that the network apparatus will indicate within a packet assignment message.
- the number n is greater than or equal to zero and is less than or equal to the number m.
- the maximum value for the number n is determined by the available network resources and by the available bandwidth of the access grant channel which carries the packet assignment message.
- n has a maximum value that is significantly less than the maximum value of m. For example the maximum value of m may be around fifty and the maximum value of n may be around 5.
- the assignor performs the assignment of packet resources based on priorities associated with the packet channel requests.
- the priorities may depend on such criteria as whether a requesting wireless terminal is requesting an emergency service, a category of user (e.g. business or private) or other criteria.
- the assignor 314 outputs the n temporary identifications sent by the n wireless terminals and contained within the received packet channel requests, together with indications of the assigned packet resources to the block scheduler 315 and to the transmitter 211.
- the block scheduler 315 allocates a radio block comprising a number of frames. For example four frames, for transmitting a packet assignment message, and indicates the radio block to the transmitter.
- the transmitter 211 transmits in the indicated radio block a single packet assignment message addressed to the group of n wireless terminals.
- the packet assignment message is divided into two parts. One part comprises assignment information that is common to the group of n wireless terminals and the other part comprises specific assignment information that is specific to individual wireless terminals of the group of n wireless terminals.
- the specific assignment information includes n sets of specific assignment information, each set being specific to an individual wireless terminal of the group of n wireless terminals. Each wireless terminal of the group uses the set of specific assignment information that is specific to that wireless terminal to set specific channel parameters for that wireless terminal to use in communicating with the network.
- FIG. 4 is a flow diagram of a process 400 for assigning a packet channel to plural wireless terminals (123-127 of FIG. 1, 220 of FIG. 2), the process 400 being suitable for use by the network apparatus 210 of Figs. 2 and 3.
- a number, m, of packet channel requests are received by the network apparatus during a time period, the packet channel requests having been transmitted by m wireless terminals such as the wireless terminal 220 of FIG. 2.
- m could be a large number, for example a number of the order of 50.
- m could be zero if no wireless terminals make requests in the time period.
- the m received packet channel requests are associated with the m wireless terminals by means of temporary identifications included in the m packet channel requests.
- the temporary identifications are used to reduce or avoid confiicts by making it less likely that two channel requests will be interpreted by the network apparatus as being the same channel request.
- n of the m received packet channel requests is identified, where n may be less than or equal to m, as described above.
- the network apparatus cannot always respond immediately to all m packet channel requests received because the network apparatus can only respond to a limited number of packet channel requests in a given time interval. This is due to limited bandwidth of the access grant channel.
- the network apparatus may only be able to respond to up to a maximum number of packet channel requests in a given time interval due to limited
- the network apparatus 210 responds to channel requests it receives. Additionally the available network packet resources may be limited. For example there may be no network packet resource that is unused and is available. The network apparatus 210 therefore identifies the n packet channel requests (a) based on bandwidth of the access grant channel and (b) based on available network packet resources. The number n may be zero and is in any case less than or equal to m.
- the network responds to the n packet channel requests by assigning packet resources of the network to the group of n wireless terminals associated with the n packet channel requests.
- the number n may be between one and four, for example.
- a single radio block comprising a number of data frames, for example four data frames, is allocated for transmission of an assignment message.
- a radio block is a set of data frames (e.g. four frames) that contain enough data to contain an assignment message or an assignment reject message.
- a single assignment message is transmitted in the single allocated radio block by the network apparatus 210 of FIG. 2.
- the assignment message indicates that network resource has been assigned to the group of n wireless terminals.
- the assignment message contains common assignment information and terminal-specific assignment information, both directed to the group of n wireless terminals.
- the common assignment information is information that is common to all of the n wireless terminals 220 addressed by the assignment message, each addressed wireless terminal 220 using the common assignment information to set parameters within the wireless terminal 220 for communicating with the network apparatus 210.
- the specific assignment information is information that is specific to individual ones of the addressed wireless terminals. Each addressed wireless terminal uses its own specific assignment information to set parameters within the wireless terminal 220 for communicating with the network apparatus 210.
- the specific assignment information includes at least one set of specific assignment information, each set being specific to an individual wireless terminal of the group of n wireless terminals, where n is between zero and m.
- Each wireless terminal of the group uses the set of specific assignment information that is specific to that wireless terminal to set specific channel parameters for that wireless terminal to use in communicating with the network.
- GPRS General Packet Radio System
- GSM Global System for Mobile communications
- GSM/EDGE Radio Access Network 3GPP
- a physical channel comprises one or more a timeslots and one or more frequencies.
- An example of a physical channel is a control channel for transmitting control data using a downlink frequency and a downlink time slot, and for transmitting control data using a corresponding uplink frequency and uplink time slot.
- Data is transmitted in data frames, and data frames are grouped into groups which contain 51 data frames.
- the groups of frames are known as 51- multiframes.
- the 51-multiframes are divided into radio blocks, each of which comprises four frames of a 51-multiframe. According to present GERAN standards, an assignment message is sent in a single radio block.
- FIG. 5 is a schematic diagram representing a network apparatus 210 and a wireless terminal 220 of a GERAN wireless communication system.
- the network apparatus 210 comprises a transmitter 211, a receiver 212 and a processor and memory subsystem 2130.
- the wireless terminal comprises a receiver 221, a transmitter 222 and a processor and memory subsystem 2230.
- the wireless terminal 220 when it requires a packet channel for sending or receiving packet data, transmits via transmitter 222 a request for a packet channel in the form of a 'PACKET CHANNEL REQUEST message' 501 over a common control channel known as the random access channel (RACH).
- the RACH can contain one or more slots of RACH data (RACH slots) per data frame.
- the network apparatus 210 of the GERAN system receives the PACKET CHANNEL REQUEST message 501 using its receiver 212.
- the network apparatus 210 can receive a PACKET CHANNEL REQUEST message in every slot of the RACH. This means that it is possible for the network apparatus 210 to receive up to 51
- PACKET CHANNEL REQUEST messages from the wireless terminal 220 and other different wireless terminals in a 51-multiframe, if 51 or more wireless terminals transmit a packet channel request within the duration of the 51 -multiframe.
- the network apparatus 210 responds to the received PACKET CHANNEL REQUEST message by transmitting, via transmitter 21 1, either a 'PACKET
- the PACKET IMMEDIATE ASSIGNMENT message indicates that the wireless terminal 220 has been assigned a packet channel.
- REJECT message 503 indicates that the wireless terminal 220 has not been assigned a packet channel, and is sent when the network does not have enough resource to allocate the requested packet channel.
- the wireless terminal 220 receives, via receiver 221, the PACKET
- the wireless terminal 220 then responds according to the PACKET IMMEDIATE
- ASSIGNMENT message 502 or ASSIGNMENT REJECT message 503. The processor
- ASSIGNMENT message by controlling the transmitter 222 of the wireless terminal 220 to transmit a signal 504 using the assigned packet channel indicated by the PACKET
- the processor 223 will respond to an ASSIGNMENT REJECT message 503 by transmitting another PACKET
- CHANNEL REQUEST message 501 after a defined time interval.
- the processor 223 initiates a cell reselection by transmitting a CELL RESELECT INITIATE signal 505.
- FIG. 6 is a diagram illustrating an arrangement for a network apparatus 210 to assign packet channels to plural wireless terminals (not shown).
- Six packet channel requests are transmitted by wireless terminals in slots x to (x+5) 601-606, on the random access channel (RACH) 407. Further packet channel requests are transmitted by other wireless terminals and are not shown in the figure.
- a wireless network apparatus 210 receives most if not all the transmitted packet channel requests, depending on signal path conditions.
- the network apparatus 210 receives the six transmitted channel requests and selects for processing m (in this example four) of the six transmitted packet channel requests, as shown by arrows 620-623.
- the network apparatus 210 selects only four of the six packet channel requests in this example because it can only respond positively to a maximum of four channel requests using a single assignment message.
- the network apparatus 210 determines that it will respond positively to n packet channel requests (where n ⁇ m) using a single assignment message.
- the determination of the number n is based on bandwidth of the access grant channel (determined by message size and frequency) and also based on available network resources.
- the network apparatus 210 can respond to up to a maximum of four channel requests by transmitting a single assignment message in a single radio block.
- n is equal to 4 because the network has enough resources to assign channels to four wireless terminals.
- the network apparatus 210 transmits an assignment message.
- the assignment message is transmitted in the form of a 'PACKET IMMEDIATE
- AGCH access grant channel
- the message indicates that network packet resource has been assigned to the addressed wireless terminals.
- the information content of the PACKET IMMEDIATE ASSIGNMENT message is described below and illustrated in the following table.
- the information content of the PACKET IMMEDIATE ASSIGNMENT message is contained in seven information elements.
- the first five of these seven information elements are:
- the last two information elements are the Channel Coding Command information element and the PACKET IMMEDIATE ASSIGNMENT (PIA) Rest Octets information element. These two information elements together contain the common assignment information and the specific assignment information referred to above in relation to Figs. 2 to 5.
- the table below shows details of the seven information elements of the PACKET IMMEDIATE ASSIGNMENT message.
- the 'PIA Rest Octets' information element is similar to a PIA Rest Octets information element used in the present GERAN standards. According to the present GERAN standards the PIA Rest Octets information element consists of a fixed number of bits which are used to assign a channel to a given wireless terminal.
- the PIA Rest Octets information element contains the same fixed number of bits but the bits are arranged differently.
- the fixed number of bits includes a common set of bits defining the common assignment information and at least one specific set of bits which together define the specific assignment information.
- Each specific set of bits defines terminal-specific assignment information used to assign a packet channel to a different wireless terminal. This means that the PACKET
- IMMEDIATE ASSIGNMENT message can carry packet assignment information for more than one wireless terminal (up to four in this example). Each specific set of bits is used to carry specific packet assignment information for an individual wireless terminal of the group.
- a wireless terminal receives the PACKET IMMEDIATE ASSIGNMENT message which contains the specific packet assignment information for the wireless terminal and may contain specific packet assignment information for one or more other terminal, together with common assignment information.
- the wireless terminal combines its own specific assignment information (as distinct from specific assignment information for other terminals) with the common assignment information to produce combined assignment information for the terminal.
- the PACKET IMMEDIATE ASSIGNMENT message provides only the essential packet assignment information for each wireless terminal requesting packet resource of the network.
- the common assignment information is defined to be common for all of the wireless terminals that are addressed by the PACKET IMMEDIATE ASSIGNMENT message.
- the specific assignment information is defined to be specific to individual terminals of the wireless terminals that are addressed by the PACKET IMMEDIATE ASSIGNMENT message.
- the assigned radio block is defined by the relative starting time.
- the relative starting time defines the number of frames from the frame number containing the packet assignment message.
- the window size is assumed to be the default value appropriate for the number of timeslots assigned. In the PACKET IMMEDIATE ASSIGNMENT message only a single time slot is assigned.
- Wireless terminals addressed by the assignment message will use a broadcast value or a default value.
- a Channel Coding Command defines the modulation and coding for the assigned uplink TBF, as follows:
- the Channel Coding Command takes one of the values from the set of coding schemes CS-1, CS-2, CS-3 and CS-4.
- the Channel Coding Command takes one of the values from the set of coding schemes MCS-1, MCS-2, MCS-3, MCS-4, MCS-5, MCS-6, MCS-7, MCS-8 and MCS-9.
- the PIA Rest Octets include:
- TBF MODE bit ( 1 ) > ; This bit only relevant for TBF assignment. 0 means GPRS TBF, 1 means EGPRS TBF
- IMMEDIATE ASSIGNMENT message for each wireless terminal of the group of wireless terminals that is addressed by the message.
- These parameters together represent specific assignment information for each of the wireless terminals in the group of n wireless terminals addressed by the message. This is denoted by the text "** 0; Repeated as many times as necessary, limited by the space in the PACKET
- the message when three wireless terminals are addressed by the message, the message contains three instances of FN OFFSET, three instances of GAMMA, three instances of Timing Advance, three instances of TFI ASSIGNMENT, and three instances of USF.
- Each instance of a parameter is directed to a specific wireless terminal of the group. The specific parameters will now be described briefly.
- An 11-bit Random Reference number is defined for each wireless terminal being addressed, and serves as a temporary identity for the wireless terminal. This random reference number is sent by a wireless terminal in a channel request message and is used by the network to distinguish between different channel requests from different wireless terminals. The random reference number is received by the wireless terminals that have sent channel requests and used by each of those wireless terminals to determine if it is likely that the PACKET IMMEDIATE ASSIGNMENT message is intended for it.
- a 6-bit frame offset number is defined as FN OFFSET and represents a number of frames offset of a frame number relative to a defined base absolute frame number FN.
- the other wireless terminals in the group transmit their signals later than the first wireless terminal by applying the frame offset value FN OFFSET.
- the base absolute frame number FN is typically the frame number of the frame during which a first wireless terminal of the group of n wireless terminals will transmit a signal in response to the PACKET IMMEDIATE ASSIGNMENT message, the first wireless terminal transmitting its signal earliest, and the other wireless terminals in the group transmitting their signals later by applying the frame offset value FN OFFSET.
- GAMMA is a 5-bit parameter which defines parameters relating to a required signal power for the transmitted signal. This value depends upon for example values of signal power levels received at the wireless terminal.
- a 6-bit Timing Advance value serves to define the timing of signals transmitted by the wireless terminal to ensure the transmitted signals are received at the network during a specified time slot.
- a 5-bit TFI information (temporary flow indicator) field serves as a further temporary identification for the wireless terminals (in addition to the random reference number).
- the TFI ASSIGNMENT field (5 bit field) is the binary representation of the Temporary Flow Identity. In downlink RLC/MAC control blocks, this field indicates the mobile station to which the control message is addressed. Further detail can be found in 3 GPP TS 44.060, section 10.4.10.
- a 3 -bit uplink status flag determines the radio block in which a wireless terminal can send data, once the assignment of a channel has been performed.
- Tl ', T2, T3, TN, "Use BCCH frequency”, and "Frequency Parameters" together represent common assignment information that is common to all of the group of n wireless terminals addressed by the PACKET IMMEDIATE
- Tl ', T2, T3 are together used to calculate the base absolute frame number FN described above.
- TN defines a time slot number for the wireless terminals to use for transmitting data. The same time slot is used by all the n wireless terminals in the group of wireless terminals addressed by the PACKET IMMEDIATE ASSIGNMENT message.
- a 1-bit TBF MODE bit is only relevant for a TBF (temporary block flow) assignment.
- TBF MODE bit When the TBF MODE bit has a value of 0, this indicates that a GPRS temporary block flow (TBF) is assigned, and when the TBF MODE bit has a value of 1 this indicates that an EGPRS TBF is assigned.
- TBF temporary block flow
- a single-bit flag (0 or 1) serves to indicate whether to use a BCCH frequency for transmitting the data. If the value of the bit is 0, then the bit indicates that the BCCH frequency shall be used. If the value of the bit is 1 , then the bit indicates that the BCCH frequency shall not be used.
- a 'Frequency Parameters' information element is used when the single-bit flag (described immediately above) has value 1.
- the Frequency Parameters information element is used to define a channel frequency other than the BCCH to use for transmitting the data. Whether or not a control channel is used, the same frequency is used by all the n wireless terminals in the group of wireless terminals addressed by the PACKET IMMEDIATE ASSIGNMENT message.
- Packet Single Block Uplink Assignment represents the first phase of a two-phase uplink assignment, each of the two phases having a different contention resolution procedure.
- the contention procedure of the second phase is more robust (using more bits of information) and therefore the second phase tends to be used when sending and receiving large amounts of data. For small amounts of data e.g. small messages, only the first phase tends to be used.
- the contention resolution of the first phase makes more efficient use of communication bandwidth but is less robust. For MTC
- a Packet Single Block Uplink Assignment is defined for each wireless terminal being addressed by the PACKET IMMEDIATE ASSIGNMENT message.
- the definition of a Packet Single Block Uplink Assignment is represented by the following pseudo code listing:
- TLLI TFI ASSIGNMENT
- GAMMA GAMMA
- Timing Advance together represent specific assignment information.
- RLC MODE RLC MODE
- TN TN
- LINK QUALITY MEASUREMENT MODE LINK QUALITY MEASUREMENT MODE
- Frequency Parameters together represent common assignment information.
- TFI AS SIGNMENT field the GAMMA field
- the Timing Advance field the TN field
- Frequency Parameters field are also present in the Packet Uplink Assignment information described earlier . Those fields will not be described again here.
- the TLLI is a 32-bit code that serves as a temporary identity for the wireless terminal while the terminal is in attached mode.
- the RLC mode information includes TN (3 -bit time slot number).
- TN (3 -bit time slot number).
- Two LINK QUALITY MEASUREMENT MODE bits serve to indicate either a GPRS TBF or an EGPRS TBF.
- the network apparatus may then optionally assign each wireless terminal additional/different resources using existing or legacy GERAN protocol procedures.
- the functions described herein may be implemented in hardware, software, firmware, or any combination thereof.
- the functions may be stored on a computer- readable medium or transmitted as one or more instructions or code over a computer- readable medium.
- Computer-readable media include any available medium that can be accessed by a computer or that facilitates transfer of a computer program or code in the form of instructions or data structures from one entity to another entity or from one place to another place.
- Computer-readable media include, but are not limited to, computer storage media, communication media, memory, optical storage, magnetic storage, or a connection.
- connection is included in the definition of computer-readable medium and can include but is not limited to coaxial cable, fiber optic cable, twisted pair, digital subscriber line (DSL), or wireless technologies such as infrared, radio, and microwave.
- DSL digital subscriber line
- disk and disc as used herein include compact disc (CD), laser disc, optical disc, digital versatile disc (DVD), floppy disk and blu-ray disc and may comprise any means for reproducing data magnetically or optically.
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Priority Applications (5)
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KR1020157012454A KR20150061660A (en) | 2010-11-11 | 2011-11-11 | Method and apparatus for assigning wireless network packet resources to wireless terminals |
JP2013538944A JP5410645B2 (en) | 2010-11-11 | 2011-11-11 | Method and apparatus for allocating wireless network packet resources to wireless terminals |
KR1020137015004A KR20130088866A (en) | 2010-11-11 | 2011-11-11 | Method and apparatus for assigning wireless network packet resources to wireless terminals |
CN201180054301.7A CN103202078B (en) | 2010-11-11 | 2011-11-11 | For the method and apparatus to wireless terminal distribution wireless network grouping resources |
EP11788716.6A EP2638759B1 (en) | 2010-11-11 | 2011-11-11 | Method and apparatus for assigning wireless network packet resources to wireless terminals |
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US41266910P | 2010-11-11 | 2010-11-11 | |
US61/412,669 | 2010-11-11 | ||
US13/294,138 US20120127951A1 (en) | 2010-11-11 | 2011-11-10 | Method and apparatus for assigning wireless network packet resources to wireless terminals |
US13/294,138 | 2011-11-10 |
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PCT/US2011/060427 WO2012065097A1 (en) | 2010-11-11 | 2011-11-11 | Method and apparatus for assigning wireless network packet resources to wireless terminals |
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US (1) | US20120127951A1 (en) |
EP (1) | EP2638759B1 (en) |
JP (1) | JP5410645B2 (en) |
KR (2) | KR20150061660A (en) |
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US9161288B2 (en) * | 2011-03-30 | 2015-10-13 | Lg Electronics Inc. | Method and device for transmitting data through client cooperation in wireless communication system |
US8797991B2 (en) * | 2011-09-16 | 2014-08-05 | Telefonaktiebolaget L M Ericsson (Publ) | Optimized system access procedures |
US9277552B2 (en) * | 2011-09-16 | 2016-03-01 | Telefonaktiebolaget Lm Ericsson (Publ) | Optimized system access procedures |
CN103781040B (en) | 2012-10-17 | 2018-02-06 | 华为技术有限公司 | Low-power consumption terminal, wireless network and communication means |
CZ306142B6 (en) * | 2013-08-26 | 2016-08-17 | Microrisc S. R. O. | Method of acknowledging messages and/or data acquisition of communication devices with packet transmission in wireless mesh networks and method of accessing such acknowledgement and data acquisition for crating a generic platform |
US20150230203A1 (en) * | 2014-02-07 | 2015-08-13 | Telefonaktiebolaget L M Ericsson (Publ) | Mobile station, access node, serving node and various methods for implementing an abbreviated page response procedure |
WO2015170469A1 (en) * | 2014-05-07 | 2015-11-12 | 日本電気株式会社 | Node, master device, and communication control system, method, and program |
WO2018030626A1 (en) * | 2016-08-08 | 2018-02-15 | 에스케이텔레콤 주식회사 | Network device and base station device, and downlink packet transmission base station reselecting method performed by same device |
US10819593B1 (en) * | 2020-01-08 | 2020-10-27 | Harness Inc. | Reporting continuous system service status based on using real-time short-term and long-term analysis techniques |
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KR100429540B1 (en) * | 1998-08-26 | 2004-08-09 | 삼성전자주식회사 | Packet data communication apparatus and method of mobile communication system |
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2011
- 2011-11-10 US US13/294,138 patent/US20120127951A1/en not_active Abandoned
- 2011-11-11 EP EP11788716.6A patent/EP2638759B1/en active Active
- 2011-11-11 WO PCT/US2011/060427 patent/WO2012065097A1/en active Application Filing
- 2011-11-11 JP JP2013538944A patent/JP5410645B2/en not_active Expired - Fee Related
- 2011-11-11 KR KR1020157012454A patent/KR20150061660A/en not_active Application Discontinuation
- 2011-11-11 CN CN201180054301.7A patent/CN103202078B/en active Active
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CN103202078A (en) | 2013-07-10 |
EP2638759A1 (en) | 2013-09-18 |
US20120127951A1 (en) | 2012-05-24 |
CN103202078B (en) | 2016-08-03 |
EP2638759B1 (en) | 2016-03-09 |
KR20150061660A (en) | 2015-06-04 |
JP5410645B2 (en) | 2014-02-05 |
KR20130088866A (en) | 2013-08-08 |
JP2013546273A (en) | 2013-12-26 |
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