JP2010537606A - Hierarchical modulation uplink interface node - Google Patents

Abstract

The wireless communication devices 102 and 122 transmit hierarchically modulated uplink (RL) WWAN signals that include a low modulation order component and a high modulation order component. In the first embodiment, the interface node 100 receives and demodulates the hierarchical modulation signal and recovers the extended data transmitted together with the high modulation order component. The interface node transmits the extension data to the base station 105 that cannot recover the high modulation order component from the UE device. In another embodiment, the low modulation order component corresponds to the first service level data and the high modulation order component corresponds to the second service level data. The interface node 120 receives and demodulates the hierarchical modulation signal to recover the second service level data, and transmits the second service level data to the receiver.
[Selection] Figure 1A

Description

  The present invention relates generally to wireless communications, and more particularly to a hierarchical modulation uplink interface node and method and a hierarchical modulation uplink interface node and a method of providing multiple service levels.

  Many wireless communication systems include geographically dispersed base stations that provide wireless services to user terminal (UE) devices such as mobile phones, wireless personal digital assistants (PDAs), and interactive pagers. The performance of the base station to receive the signal transmitted from the UE device is such as the distance between the UE device and the base station, noise, obstacles, the number of other devices communicating with the base station, the type of signal modulation, etc. It depends on various factors. Modulation schemes that provide higher data rates are not easily demodulated at the base station because the base station must decode between signal components that are closer together than the low modulation order signal. A low modulation order may be used for uplink signal transmission, but only less data can be transmitted.

  Therefore, there is a need for a hierarchical modulation uplink interface node, that is, a hierarchical modulation uplink interface node for providing a plurality of service levels.

  In one embodiment, a user equipment (UE) device transmits a hierarchically modulated uplink (RL) WWAN signal comprising a low modulation order component and a high modulation order component to a base station in a wireless wide area network (WWAN). To do. The interface node intercepts the hierarchical modulation signal and transmits data recovered from the high modulation order component to the WWAN.

  In another embodiment, a user equipment (UE) device transmits a hierarchical modulation uplink (RL) WWAN signal to an interface node and a base station in a wireless wide area network (WWAN). The hierarchical modulation signal includes a low modulation order component corresponding to the first service level data and a high modulation order component corresponding to the second service level data. The interface node intercepts the hierarchical modulation signal and transfers the second service level data recovered from the high modulation order component to the receiver via the communication network.

FIG. 1A is a block diagram of an interface node in communication with a user equipment (UE) device and a wireless wide area network (WWAN), according to an exemplary embodiment of the invention. FIG. 1B is a block diagram of an interface node in communication with a user equipment (UE) device and a wireless wide area network (WWAN), according to another exemplary embodiment of the present invention. FIG. 2 is a block diagram of an interface node that communicates with a UE device and a WWAN via a network according to one embodiment. FIG. 3 is a flowchart of a method performed in a UE device according to an exemplary embodiment of the present invention. FIG. 4A is a flowchart of a method performed at an interface node according to an exemplary embodiment of the present invention. FIG. 4B is a flowchart of a method performed at an interface node according to another exemplary embodiment of the present invention. FIG. 5 is a block diagram of the hierarchical modulation function in the UE device. FIG. 6 is an explanatory diagram for mapping component data bits to stacked modulation symbols. FIG. 7 is a graphical representation of a typical 16-QAM array illustrating the hierarchical modulation symbols generated by the hierarchical modulation device. FIG. 8 is a block diagram of a typical WWAN receiver for performing hierarchical modulation at an interface node.

  FIG. 1A shows communication with a user equipment (UE) device 102 and a wireless wide area network (WWAN) 104 when a base station 105 in the wireless wide area network (WWAN) cannot recover the high modulation order component of the hierarchical signal 106. It is a block diagram of the interface node 100 to do. The interface node 100 assists the operation of the WWAN by transferring the data 112 transmitted by the UE device 102 to the WWAN when the base station 105 in the wireless wide area network (WWAN) cannot recover the data 112. . As will be described in more detail below, the UE device 102 generates a hierarchical modulation signal 106 including a high modulation order component 108 and a low modulation order component 110 and transmits the hierarchical modulation signal 106 to the base station 105. Depending on the communication channel 114 between the UE device 102 and the base station 105, the base station 105 cannot recover the high modulation order component 108. For example, due to distance, obstacles, noise, multipath interference, and / or other factors, the signal-to-noise ratio of the signal may not be suitable for the base station 105 to receive. However, the low modulation order component 110 can be recovered after transferring the signal 106 via the channel 114. For example, if the high modulation order is 16 quadrature amplitude modulation (QAM) and the low modulation order is quadrature phase shift keying (QPSK), the base station 105 can distinguish 4 points in the QPSK array. However, it may not be possible to determine which of the 16 points in the QAM array has been transmitted. If the quality of the communication channel 116 between the UE device 102 and the interface node 100 is sufficient, the interface node 100 recovers the high modulation order component 108 and recovers the data 112 transmitted using the high modulation order. In addition, the signal 106 can be demodulated. The interface node transfers the data 112 to the base station 105.

  Under some circumstances, the base station 105 cannot recover the low modulation order component 110 or the high modulation order component 108 depending on the state of the channel 114. In such a situation, data corresponding to both components may be transferred from the interface node 100 to the WWAN 104. However, for the situation described with reference to FIG. 1A, the state of the channel 114 is that the base station 105 can demodulate the low modulation order component 110 but cannot demodulate the high modulation order component 108. Accordingly, in FIG. 1A, the low modulation order component 110 at the base station 105 is indicated by solid arrows and solid blocks, the high modulation order component 108 is indicated by broken arrows and dashed blocks, and the low modulation order component 110 can be recovered by the base station 105. The high modulation order component 108 represents that it cannot be recovered by the base station 105.

  The channel used to transmit data 112 from interface node 100 to base station 105 may be a wired communication channel or a wireless communication channel, and may include any combination of networks, devices, and / or devices. Examples of suitable communication channels include wired and wireless IP protocol channels, including the Internet or intranet, and point-to-point microwave channels.

  FIG. 1B is a block diagram of an interface node 120 that provides multiple service level communication services in communication with a user equipment (UE) device 122 and a wireless wide area network (WWAN) 124. The UE device 122 transmits the hierarchical signal 126 to the base station 125 in the WWAN and the interface node 120 in which at least two service levels are provided to the user in uplink communication. In an exemplary embodiment, the first service level facilitates transmission of real-time data such as real-time voice transmission, and the second service level facilitates transmission of delay-tolerant data such as email and file uploads. . As described in more detail below, the UE device 122 generates a hierarchical modulation signal 126 that includes a low modulation order component 130 that includes first level service data and a high modulation order component 128 that includes second level service data. And transmit. Therefore, in the example described herein, the first level service data is real-time data, and the second level service is delay tolerance data.

  Depending on the communication channel 124 between the UE device 122 and the base station 125, the base station 125 cannot recover the high modulation order component 128. For example, the signal to noise ratio of the signal may not be appropriate for reception at the base station 125 due to distance, obstacles, noise, multipath interference, and / or other factors. However, the low modulation order component 130 can be recovered after transmitting the signal 126 via the channel 134. For example, if the high modulation order is 16 quadrature amplitude modulation (QAM) and the low modulation order is quadrature phase shift keying (QPSK), the base station 125 can distinguish 4 points in the QPSK array. However, it may not be possible to determine which of the 16 points in the QAM array has been transmitted. If the quality of the communication channel 136 between the UE device 122 and the interface node 120 is sufficient, the interface node 120 recovers the high modulation order component 128 and recovers the data 132 transmitted using the high modulation order. Therefore, the signal 126 can be demodulated. The interface node transfers data 132 to the recipient.

  Any of a number of techniques for managing communication via the interface node 120 may be used. In one embodiment, the interface node 120 transmits information regarding a communication link between the UE device 122 and the interface node 120 to the base station 125. Based at least on the quality of the link, the base station 125 assigns a suitable modulation order to the UE device 122 to transmit the second level of service data. In some situations, this allocation may be made based on the type and volume of data, availability of communication resources, user priority levels and / or other factors.

  Under some circumstances, the base station 125 cannot recover the low modulation order component 130 or the high modulation order component 128 depending on the state of the channel 134. In such a situation, the low modulation order component data may be transferred from the interface node 100 to the WWAN 104. However, for the situation described with reference to FIG. 1B, the state of channel 134 is that base station 125 can demodulate low modulation order component 110.

  Also, the base station 125 does not demodulate the high modulation order component even if the channel state is appropriate. Accordingly, in FIG. 1B, the low modulation order component 130 at the base station 125 is indicated by solid arrows and solid blocks, the high modulation order component 128 is indicated by dashed arrows and dashed blocks, and the low modulation order component 130 can be recovered by the base station 125. , Indicating that the high modulation order component 128 is not recoverable by the base station 125.

  In some situations, interface node 120 may have to demodulate the low modulation order component, but in typical embodiments, interface node 120 does not demodulate the low modulation order component. Thus, in FIG. 1B, low modulation order component 130 at interface node 120 is indicated by dashed arrows and dashed blocks, high modulation order component 128 is indicated by solid arrows and solid blocks, and high modulation order component 108 is recoverable by interface node 120. , Indicating that the low modulation order component 130 is not recovered by the interface node 120. The channel used to transmit the second service level data 132 from the interface node 120 to the intended recipient may be a wired communication channel or a wireless communication channel, and any combination of networks, devices and / or devices. May be included. Examples of suitable communication channels include wired links, including the Internet or intranet, and wireless IP protocol channels and point-to-point microwave channels.

  Referring to FIGS. 1A and 1B, WWAN 104, 124 and UE devices 102, 122 are part of a wireless communication system 118, 138 that includes any number of base stations and infrastructure. The principles described herein may be applied to any of a number of communication systems, protocols, arrangements and configurations, and wireless communication systems 118, 138 may be implemented in accordance with a WWAN system such as a cellular communication system. The Examples of some suitable communication technologies include those that operate in accordance with code division multiple access (CDMA) standards such as cdma2000 1X, 1xEV-DO, and W-CDMA. In some situations, the wireless communication systems 118, 138 may operate in accordance with other standards, such as, for example, an OFDM-based standard or a GSM standard. The wireless communication system 118, 138 includes a number of geographically distributed base stations 105, 125 that provide radio services to UE devices 102, 122 in a geographical area. The interface nodes 100 are geographically distributed and communicate with one or more base stations via a wireless channel or a wired channel. Base stations 105 and 125 may communicate with any number of interface nodes and UE devices 102 and 122. In some situations, interface nodes 100, 120 are implemented within a wireless local area network (WLAN) access point (AP) that is part of a WLAN.

  Any number of devices, circuits, components, etc. may be used to implement the various functions and operations of the blocks described with respect to the wireless communication systems 118, 138. Two or more functional blocks may be integrated into one device, and the functions described as being performed in one device may be performed by several devices. For example, at least a partial function of the base station 105 may be performed by a base transceiver station (BTS), a base station controller (BSC), a mobile switching center, or the like under certain circumstances. Furthermore, depending on the situation, other combinations of modulation orders can be used. Examples of other suitable combinations include BPSK and QPSK, QPSK and 16-QAM, 16-QAM and 64-QAM, 64-QAM and 256-QAM, and other combinations thereof. Further, the hierarchical modulation scheme may include more than two modulation orders. For example, BPSK can be used for low modulation orders, QPSK can be used for intermediate modulation orders, and 16-QAM can be used for high modulation orders. Other combinations are possible using a phase offset (eg, offset-QPSK).

  FIG. 2 is a block diagram of interface nodes 100, 120 in communication with WWAN 104, 124 and UE devices 102, 122, according to an exemplary embodiment as shown in FIGS. 1A and 1B. The WWANs 104 and 124, the base stations 105 and 125, the UE device, and the interface nodes 100 and 120 may be implemented using any combination of hardware, software, and / or firmware. In realizing various functions and operations of the blocks described with respect to the base stations 105 and 125, the interface nodes 100 and 120, and the UE devices 102 and 122, there may be any number of devices, circuits, components, or the like. . Further, two or more functional blocks may be integrated into one device, and the functions described as being performed in one device may be performed by several devices.

  Each UE device 102, 122 includes a radio frequency including at least one antenna 202, a processor 204, a memory 206, a transmitter (TX) 210 and a receiver (RX) 212 for communicating with the base stations 105, 125. And an air interface including a transmission / reception unit 208. In addition, these UE devices 102 and 122 having a multi-mode function include another network interface for communicating with a WLAN access point and a transmission / reception unit. The processor 204 and the transmission unit 210 are configured to perform hierarchical modulation and transmit the hierarchical modulation signals 106 and 126. The processor 206 typically performs baseband processing of digitized information, including modulation / demodulation, encoding / decoding, interleaving / deinterleaving, multiplexing / demultiplexing, error correction operations, etc. . Examples of suitable processor 204 include implementing functionality in one or more digital signal processors (DSPs) and / or application specific integrated circuits (ASICs). The memory 206 has a function of storing one or more software programs executed by the processor 204, and information regarding identification data, a protocol, and other data.

  Referring to FIGS. 1A and 2, in an exemplary embodiment, UE device 102 transmits hierarchically modulated signal 106 to base station 105 that at least attempts to demodulate both components 108, 110. The base station hierarchically demodulates the received hierarchical signal 106. In many cases, base station 105 successfully recovers data transmitted on both components. However, in some situations, the channel 114 between the UE device 102 and the base station 105 is not of sufficient quality to cause the base station 105 to recover one or both of the components 108, 110. In an exemplary embodiment, the base station 105 notifies the interface node 100 whether there is data that cannot be recovered. The base station 105 notifies the interface node 100 of data to be transferred to the WWAN 104 because the base station 105 cannot recover directly or via the WWAN infrastructure 234. In response, interface node 100 forwards the appropriate data to WWAN 104 as described in detail below. As an example, high modulation order component data may be transferred to WWAN 104 without receiving communication from base station 105 or WWAN 104.

  Referring to FIGS. 1B and 2, in an exemplary embodiment, UE device 122 transmits hierarchical modulated signal 126 to base station 125 that demodulates only low modulation order component 130. The base station 125 hierarchically demodulates the received hierarchical signal 126 to recover the first service level data. In an exemplary embodiment, the first service level data includes real-time voice information to facilitate a two-way call.

  The interface nodes 100 and 120 include at least a WWAN receiving unit 214 for receiving a WWAN signal from one or more UE devices 102 and 122 and a network interface 222 for communicating with the WWANs 104 and 124. In the exemplary embodiment, the WWAN receiver 214 is part of a WWAN transceiver 216 that includes a WWAN transmitter 218 for facilitating bi-directional communication with the UE devices 102, 122. Depending on the situation, the WWAN transmitter can be omitted. If the interface nodes 100, 120 are implemented as part of a WLAN access point, the access point also includes hardware and software for providing WLAN services. The interface nodes 100 and 120 further include a controller 220 connected to the WWAN interface 222 and the WWAN receiving unit 214. The controller 220 performs the control functions described herein, as well as other functions and facilitates the overall operation of the interface nodes 100, 120. The controller 220 is connected to or comprises a memory 224 that may include one or more random access memory (RAM) and / or read only memory (ROM) storage.

  The network interface 222 includes any combination of hardware, software and / or firmware for transmitting the high modulation order component data 112, 132 to the WWAN 104, 124. In the exemplary embodiment, wired interface 226 communicates via access router 228 and / or IP network 230 with access gateway 232 in WWAN infrastructure 234 that serves base stations 105, 125. Wired interface 226 exchanges messages with access router 228 and Internet Protocol (IP) network 230. Wired interface 226 provides packet data communication and facilitates access to access gateway 232 in the Internet and WWAN infrastructure 234 via access router 228. In some situations, the wired interface 226 may be implemented at least partially disconnected from the network interface 222. The access router 228 may be connected to another interface node 100 or 120 or a WLAN access point, and may provide a communication management control function for the WLAN. Depending on the circumstances, the access router 228 may be implemented in or removed from the interface node 100, 120 or WLAN access point. Depending on the situation, the connection between the access gateway 232 and the interface nodes 100, 120 may include, for example, a satellite communication link or a wireless communication link such as a point-to-point microwave link. Further, the interface nodes 100 and 120 may use a wireless backhaul such as WiMax or a point-to-point link. In that case, the network interface 222 includes a wireless interface transmission / reception unit 240 for communicating with the base stations 105 and 125 or devices connected to the base stations 105 and 125. Therefore, the wireless reception unit may be located in the base stations 105 and 125 or may be located anywhere in the WWAN 104 or 124. In FIG. 2, the wireless interface transmission / reception unit 240 is indicated by a broken line block, and indicates that the wireless interface transmission / reception unit 240 is not necessary when the wired interface 226 provides communication to the WWANs 104 and 124. Therefore, the wireless interface transmission / reception unit 240 may replace the wired interface 226, may be included with the wired interface 226, or may be omitted.

  The WWAN receiving unit 214 is configured to receive the hierarchical modulation signals 106 and 126 from the at least one UE device 102 and 122. As described with reference to FIG. 1A, the hierarchical modulation signal 106 includes a low modulation order component 110 and a high modulation order component 108. The WWAN receiving unit 214 demodulates the hierarchical modulation signal 106 and recovers the higher-order modulated data stream. This higher order modulated data stream is then modulated for transmission to the base station 105 or otherwise processed. The base station attempts to demodulate the high modulation order component, but in some situations only the low modulation order component is recovered. Accordingly, in such a case, the hierarchical modulation signal 106 includes a low modulation order component 110 that can be recovered by the base station 104 when the WWAN hierarchical modulation signal is transmitted to the base station 104 via the communication path 114; And a high modulation order component 108 that cannot be recovered by the base station 104 after being transmitted via the communication path 114. As described with reference to FIG. 1B, the hierarchical modulation signal 106 includes a low modulation order component 110 and a high modulation order component 108. The WWAN receiving unit 214 demodulates the hierarchical modulation signal 106 and recovers the higher-order modulated data stream. This higher order modulated data stream is then modulated for transmission to the recipient or otherwise processed. The low modulation component corresponds to the first service level data, and the high modulation order corresponds to the second service level data.

  In addition to other information, the memory 224 stores a communication device identification value corresponding to each communication device 102, 122 serviced by the interface nodes 100, 120. The communication device identification value may include an electronic serial number (ESN) or other unique data. The identification value may be stored in the interface node 100 using any of a number of techniques. Examples of suitable methods for storing the identification value include a method of storing the identification value during installation of the interface node 100 or during an initialization process performed during periodic updates to the interface nodes 100, 120. . In the exemplary embodiment, the identification information received from the WWAN infrastructure 234 includes an identification value that identifies the UE devices 102, 122 near the interface nodes 100, 120. Therefore, the user list of the monitoring target device by the interface nodes 100 and 120 can be updated with the identification information. As an example, only the identification value received from the WWAN infrastructure 234 may be stored in the user list. In other situations, the user list may include a combination of pre-programmed identification values and values received from the WWAN infrastructure. The identification information may include parameters, numbers, identifiers, or any combination of information that provides suitable data for identifying a particular UE device 102, 122 to the interface node.

  In an exemplary embodiment, WWAN infrastructure 234 comprises a packet switched backbone network that includes at least one access gateway 232. The controller 236 includes a processor, computer, processor arrangement, or other processing device. Here, the controller 236 may perform at least some functions of the access gateway. The controller includes a positioning processor such as a positioning entity (PDE) and / or a location server. Memory 238 includes a suitable memory device such as a RAM or ROM that provides electrical storage of information. In addition to other types of information, the memory stores identification information and information regarding the location of the interface nodes 100, 120. The access router 228 may be connected to the access gateway 232 using any combination of wired and wireless connections. Examples of suitable connections include T1 lines, optical cables, coaxial cables, and point-to-point microwaves. The access gateway 232 is a communication interface that allows the interface nodes 100, 120 to communicate with the WWAN infrastructure 234. Various components and functions of the WWAN infrastructure 234 may be implemented using a number of devices distributed throughout the backbone network. For example, the processing function of determining which UE device 102, 122 should be monitored may be performed in servers connected to PDEs at different locations.

  Referring to FIGS. 1A and 2, in operation, the interface node 100 monitors the uplink WWAN channel including the uplink hierarchical modulation signal 106 transmitted from the UE device 102. The uplink WWAN receiving unit 214 is adjusted or set, and the uplink hierarchical modulation signal 106 is received. As described in more detail below, the hierarchical signal 106 is received and demodulated to recover the high modulation component 108. The recovered data stream 112 is transferred to the base station via the network interface 222.

  Any of a number of techniques for managing communication via the interface node 100 may be used. Accordingly, the type, number, and size of messages for transmitting control signals and data flows between the interface node, WWAN 104, and base station 105 depend on a particular management scheme. In an exemplary embodiment, the interface node 100 transmits information regarding a communication link between the UE device 102 and the interface node 100 to the base station 105. Based at least on the quality of the link, the base station 105 assigns a suitable modulation order to the UE device 102 for transmitting the low modulation order data and the high modulation order data. In some situations, this allocation may be made based on the type and volume of data, availability of communication resources, user priority level, and / or other factors. Further, based on the quality of the channel, the base station 105 instructs the interface node to transfer the high modulation order data to the WWAN, to transfer both the high modulation order data and the low modulation order data, or any Data is not sent. This indication may be valid for a specified number of frames, length of time, session or other time period.

  Referring to FIGS. 1B and 2, in operation, the interface node 120 monitors the uplink WWAN channel including the uplink hierarchical modulation signal 126 transmitted from the UE device 122. The uplink WWAN receiving unit 214 is adjusted or set, and the uplink hierarchical modulation signal 126 is received. In an exemplary embodiment, the base station 125 is informed about the quality of the communication link between the UE device 122 and the interface node. When the UE device 122 is detected, the interface node 120 monitors the communication channel 136 and generates a channel quality indicator based on the quality. The channel quality indicator may be any of a number of parameters or features. Examples of suitable quality indicators include received signal strength and signal-to-noise ratio (SNR). The channel quality indicator is transferred to the base station 125, and the base station 125 performs resource allocation, modulation scheme, and transmission schedule allocation to the UE device 122 using the transferred information. The resource allocation may be performed based on other factors, such as available capacity, uplink transmission request bandwidth, and user priority.

  Once the transmission schedule is established, suitable information is sent to the interface node 120 and the UE device 122. A communication parameter is assigned to the UE device 122 using a control method using a known technique. The interface node 100 receives a signal transmitted from the UE device 122 using information provided by the base station 105. As will be described in more detail below, the hierarchical signal 126 is demodulated and the high modulation component 128 is recovered. The recovered data stream (second service level data) 132 is transferred to the recipient via the network interface 222. Data 132 may be sent over any number of networks or systems before being received by the recipient. For example, the data 132 may include an email transmitted to the wireless mobile device via the Internet and a WWAN system or a WLAN system.

  FIG. 3 is a flowchart of a method performed in the UE devices 102, 122 according to an exemplary embodiment of the present invention. The method may be performed using any combination of hardware, software and / or software in the UE device 102, 122, but in an exemplary embodiment, by executing the software code of the processor, At least partially done.

  In step 302, the UE apparatuses 102 and 122 receive communication parameters indicating at least a transmission modulation order from the base stations 105 and 125. The base stations 105 and 125 transmit control signals for assigning a low modulation order and a high modulation order for uplink transmission from the UE apparatuses 102 and 122 by a known control technique. Other parameters such as power control level and timing information are also assigned. The assignment of the high modulation order may be a response to a request from the UE devices 102, 122 for communication resources as well as voice communication.

  In step 304, hierarchical modulation is performed to generate a hierarchical modulation signal. The basic data signal and the extended data signal are modulated and interleaved to create a hierarchical signal that includes data from both data signals. According to the embodiment described in FIG. 1A, both data signals contain information to be received by the base station, but in some cases the priority levels may be different. Examples of data signals include a basic data signal containing audio information and an extended data signal containing upstream digital data. In other cases, control data may be transmitted on the extended data signal, or user data may be transmitted using the basic data component. According to the embodiment described in FIG. 1B, the hierarchical modulation signal 126 may be formed by combining first level service data such as voice and second level service data such as delay tolerance data.

  In step 306, the hierarchical modulation signal is transmitted. In many cases, the communication path 114 from the UE device to the base station 105 is different from the communication path 116 to the interface node 100.

  FIG. 4A is a flowchart of a method performed at the interface node 100 according to the exemplary embodiment of the invention shown in FIG. 1A. The method may be performed using any combination of hardware, software and / or firmware in the interface node 100, but in an exemplary embodiment, by executing software code in the controller 220, At least partially done.

  In step 402, hierarchical modulation signal 106 is received from UE device 102. In the exemplary embodiment, hierarchical modulation signal 106 is an uplink (RL) WWAN signal received via communication path 116 from UE device 102 to interface node 100. The hierarchical modulation signal 106 includes a low modulation order component 110 corresponding to the basic data signal and a high modulation order component 108 corresponding to the extended data signal.

  In step 404, the high modulation order component is demodulated. As described in more detail below, the extended data signal is recovered by hierarchical demodulation, deinterleaving, and decoding. In some cases, both the low modulation order component and the high modulation order component are recovered.

  In step 406, a request for high modulation order component data is received from the WWAN. In some cases, the request may include a request for low modulation order component data. In the exemplary embodiment, WWAN 104 generates a request based on an indication from base station 105 that one or more of the components of signal 106 cannot be received. The WWAN transmits a request to all the interface nodes 100 in the area of the UE device 102.

  In some situations, step 406 can be omitted, and the high modulation order component can be continuously recovered and continuously transferred to the network. Also, the low modulation order can be recovered and transferred continuously.

  In other situations, the interface node 100 may determine whether to transmit low modulation order component data and / or high modulation order component data based on the threshold. For example, the threshold may be based on signal-to-noise ratio (SNR) or signal strength of the received signal at the interface node, and / or SNR or signal strength of the signal 106 at the base station 105. Information regarding the signal 106 received at the base station 105 may be periodically transmitted from the WWAN or the base station to the interface node.

  In step 408, the extension signal is transmitted. In the exemplary embodiment, the extended data signal (high modulation order component data) is transmitted to WWAN 104. The extended data signal is formatted, modulated, or processed to form a signal for transmission to the WWAN 104. The signal may be generated and transmitted using many wired and / or wireless technologies. In an exemplary embodiment, the extended data signal (high modulation order component data) is transmitted over a network connected to the WWAN infrastructure 234. In some cases, the high modulation order component data is transmitted directly to the intended recipient. For example, if the high modulation order component data is an email, the email may be sent directly over the IP network rather than sent to the WWAN infrastructure. In some situations, the extended data signal is transferred to the base station 105. Further processing may be required to integrate the extended data signal and the basic data signal. Such processing can be performed at the base station 105 anywhere within the WWAN infrastructure 104 or within the network.

  FIG. 4B is a flowchart of a method performed at the interface node 120 according to the exemplary embodiment of the invention described in FIG. 1B. The method may be performed using any combination of hardware, software and / or firmware in the interface node 120, but in an exemplary embodiment, by executing software code in the controller 220, At least partially done.

  In step 422, the channel quality indicator is transmitted to the base station 125. After the interface node 120 detects the UE device 122, the channel 136 is monitored by evaluating a signal transmitted from the UE device 122. In an exemplary embodiment, the interface node 100 uses information provided by the WWAN to receive and demodulate uplink signals transmitted to the base station 125. One or more channel quality parameters such as signal to noise ratio, signal strength, signal attenuation, or bit error rate (BER) are generated and transmitted to the base station 125.

  In step 424, uplink communication parameters are received from the base station 125. The uplink communication parameter provides information on allocation of communication resources to the UE device 122, and provides at least a modulation order and schedule information allocated to the UE device 122.

  In step 426, hierarchical modulation signal 126 is received from UE device 122. Hierarchical modulation signal 126 is an uplink (RL) WWAN signal received via communication path 136 from UE device 122 to interface node 120. The hierarchical modulation signal 126 includes a low modulation order component 130 corresponding to the basic data signal and a high modulation order component 128 corresponding to the extended data signal.

  In step 428, the high modulation order component is demodulated. As described in more detail below, the extended data signal is recovered by hierarchical demodulation, deinterleaving, and decoding. In some cases, both the low modulation order component and the high modulation order component are recovered.

  In step 430, the second service level data (extended component) is transferred to the recipient. In an exemplary embodiment, a communication link is established with the network and possibly the recipient's user terminal before the extension component is transferred. For example, if the second service level data is an email, the interface node 120 establishes a communication link with the Internet and transmits the email message using the IP protocol.

  The extended data signal is formatted, modulated, or processed to form a signal for transmission to the WLAN where the network or interface node 120 is part of or connected to the WLAN access point. To do. The signal may be generated and transmitted using many wired and / or wireless technologies. In an exemplary embodiment, the extended data signal (second service level data) is transmitted over the IP network 230. Depending on the situation, the extended data signal is forwarded to the base station 125 or the WWAN 124.

  FIG. 5 is a block diagram of the hierarchical modulation function in the UE devices 102 and 122. The functional blocks illustrated in FIG. 5 are realized by at least a part of the transmission unit 210, the memory 206, and the processor 204 of the UE devices 102 and 122 in the exemplary embodiment. However, there may be any number of components implemented in any combination of devices, circuits or software, hardware and / or firmware in implementing the various functions and operations of the blocks described with respect to FIG. Also good. Two or more functional blocks may be integrated into one device, and the functions described as being performed in one device may be performed by several devices.

  Basic data signal 500 is received at basic component encoder 502, and extended data signal 504 is received at extended component encoder 506. Basic data signal 500 and extended data signal 504 may include any of a number of types of data and signals. In one embodiment shown in FIG. 1A, examples of the basic data signal 500 and the extended data signal 504 include two streams from the same data source: real-time and best effort data, control and data, and voice and data signal. May be included. In the embodiment shown in FIG. 2A, data and signals correspond to first service level data and second service level data, respectively.

  With continued reference to FIG. 5, each data signal is encoded and processed by known techniques before the signal is interleaved by the base interleaver 508 and the extended component interleaver 510. Encoders 502, 506 and interleavers 508, 510 provide error correction processing and may employ suitable error correction coding such as turbo coding. Interleavers 508 and 510 may employ any suitable interliving algorithm. The encoding and interleaving scheme used by one component may be different from that used by another component.

  A multiplexing unit (MUX) 512 multiplexes the interleaved signal before the hierarchical modulation unit 514 modulates the multiplexed signal. Multipliers 516, 518, and 520 multiply Walsh codes (Wo, Wc) by the in-phase and quadrature components and pilot signal 522, respectively. Gain multipliers 524, 526, and 528 adjust the gains of the in-phase component, quadrature component, and pilot signal, respectively. A time division multiplexing unit (TDM) 530 time division multiplexes the pilot signal, the in-phase signal, and the quadrature signal, and generates a hierarchical modulation signal 206 transmitted by the transmission unit 210 via the antenna.

  FIG. 6 is a block diagram in which bits are mapped to stacked modulation symbols. Each of the base component and the enhancement component is individually encoded and interleaved by interleavers 508 and 510. The outputs Bi and Ej are multiplexed by the multiplexing unit 514, and symbols S0, S1, S2, and S3 are generated. Multiplexing differs depending on the number of parameters constituting the basic component. For example, instead of alternating each bit of the multiplexing component, three extension bits may follow each basic bit.

  FIG. 7 is a graph illustrating a 16-QAM array 700 that describes the hierarchical modulation symbols generated by the hierarchical modulation unit 514. In this example, each modulation symbol represents four multiplexed bits (ie, S3, S2, S1, S0). S0 and S2 represent multiplexed bits from the basic component, and S1 and S3 represent multiplexed bits from the extended component. The modulation symbol is configured so that S0 and S2 do not change within the same quadrant. Thus, the multiplexed bits from the base component are essentially QPSK modulated, while the multiplexed bits from the extension component are 16-QAM modulated.

  As shown in FIG. 5, the basic component and the extension component are modulated and transmitted together with the pilot signal. The pilot gain (Gp) is independent of the gain for basic and extended (Gb). In order to improve the reception of the fundamental component, the UE devices 102, 122 can adjust the gain Gb so that the fundamental data signal can be successfully demodulated when the interface node 100 successfully receives the pilot signal.

  FIG. 8 is a block diagram of a typical WWAN receiving unit 214 that performs hierarchical modulation in the interface node 100. In addition to the other components, the reception unit 214 includes a reception unit side front end (RX FE) 801, a delay buffer 802, a Walsh code (W0, WC) and a coefficient (W *) multiplication unit 804, 806, 808, 810. 812, a channel estimation unit 814, a threshold comparator 816, and a hierarchical demodulation unit 818. After the pilot is scrambled using the Walsh code W0, channel estimation is performed to estimate the weight, W *, and SNR. The delayed data is scrambled using the Walsh code WC and then equalized using the coefficients. Depending on the SNR of the current signal, either QPSK or 16-QAM demodulation can be used. The reception unit 214 includes a basic component deinterleaver 826 and a decoder 828, and an extended component deinterleaver 822 and a decoder 824. In some situations, the basic deinterleaver 826 and the basic decoder 828 may be omitted. At least some of the functional blocks may be executed in the controller 220. However, there may be any number of components implemented in any combination of devices, circuits or software, hardware and / or firmware in implementing the various functions and operations of the blocks described with respect to FIG. Also good. Two or more functional blocks may be integrated into one device, and the functions described as being performed in one device may be performed by several devices.

  The channel evaluation unit 814 provides the signal strength index and C / l to the threshold comparator 816 that determines the modulation order used by the hierarchical modulation unit 818. The threshold comparator 816 can include one or more look-up tables (LUTs) and stores signal to noise ratio (SNR) ranges and corresponding modulation order values. The LUT for the SNR may be updated based on the pilot gain (GP) and the relative level of the gain used in the fundamental component, since the transmitted pilot level may vary with traffic conditions. The LUT may include code rate information. If the threshold comparator 816 indicates that the SNR is good (below the threshold), both the base and extended components can be successfully demodulated using the 16-QAM demodulator.

  However, if the threshold comparator 816 indicates that the SNR is low, only the fundamental component can be successfully demodulated. In this case, for each received 16-QAM symbol, the stacked demodulator 818 only needs to determine which quadrant has the lowest error probability. Instead of selecting from the 16 possible 16-QAM symbols, the stacked demodulator 818 only needs to make a decision based on the four possible outcomes (similar to QPAK demodulation). This is possible because the modulation symbols for each quadrant do not change with respect to the base component bits. As described above, other combinations of modulation orders can be used in some situations.

  Alternatively, the receiver may monitor the signal strength (at both the relay station and the base station) and recover the signal without threshold comparison. In this case, the receiving unit always demodulates both the basic component and the extended component. The base component and the extended component may indicate successful recovery of the overhead message by the result of error checking such as CRC (Cyclic Redundancy Check) of each component or equivalent.

  In the embodiment shown in FIG. 1B, since the UE device 102 can use a plurality of QoS communications for a single transmission, resources such as a battery and control signaling overhead can be used effectively. Multiple services are provided in a single session. Also, the use of WWAN uplink traffic resources is minimized for transmissions that require only control signaling to facilitate multiple service transmissions.

  It will be apparent to those skilled in the art that other embodiments and variations of the present invention can be readily conceived from the perspective of these techniques. The above description is intended to be illustrative and not limiting. The present invention is limited only by the following claims, which include all of the other embodiments and modifications when considered in conjunction with the above specification and the accompanying drawings. . The scope of the invention should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the appended claims along with their full scope of equivalents.

Claims (20)

A receiver that receives a wireless wide area network (WWAN) hierarchical modulation signal that is transmitted from a user equipment (UE) device and includes a low modulation order component and a high modulation order component;
A demodulator that demodulates the high modulation order component to recover high modulation order component data;
A network interface that transmits the high modulation order component data to the WWAN. The low modulation order component corresponds to a first service level data signal;
The interface node of claim 1, wherein the high modulation order component corresponds to a second service level data signal.   The network interface of claim 1, wherein the network interface is configured to transmit the high modulation order component data to the WWAN when a base station in the WWAN is unable to recover the high order component data from the hierarchical modulation signal. Interface node.   The interface node according to claim 1, wherein the network interface includes a wireless transmission unit that transmits the high modulation order component data.   The interface node according to claim 3, wherein the wireless transmission unit is a WWAN transmission unit that transmits the high-order component data to the base station via a WWAN wireless channel.   The interface of claim 1, wherein the network interface is configured to transmit the high modulation order component data to the WWAN when a signal to noise ratio of the WWAN hierarchical modulation signal received at the base station is lower than a threshold. node.   The interface node of claim 1, wherein the network interface comprises an access router for connecting to a wired communication network.   The interface node according to claim 7, wherein the wired communication network includes the Internet and an access gateway.   The high modulation order component is modulated by a modulation selected from the group consisting of QPSK, 16-QAM, 64-QAM, and 256-QAM, and the low modulation order is BPSK, QPSK, 16-QAM, and 64- The interface node of claim 1, modulated by a modulation selected from the group consisting of QAM.   The interface node according to claim 2, wherein the first service level data is real-time data, and the second service level data is delay tolerance data. The user terminal device
A multiplexing unit that multiplexes the basic data signal and the extended data signal to generate a multiplexed data stream;
The wireless wide area network (WWAN) hierarchical modulation comprising modulating the multiplexed data stream to include the low order modulation component corresponding to the basic data signal and the high order modulation component corresponding to the extension data signal A modulation unit for generating a signal;
2. The interface node according to claim 1, further comprising: a WWAN transmission unit that transmits the WWAN hierarchical modulation signal to the interface node via a first communication path and transmits to the base station via a second communication path. The user terminal device
A multiplexing unit that multiplexes the first service level data signal and the second service level data signal to generate a multiplexed data stream;
The wireless wide area comprising the low order modulation component corresponding to the first service level data signal and the high order modulation component corresponding to the second service level data signal by modulating the multiplexed data stream A modulation unit for generating a network (WWAN) hierarchical modulation signal;
The interface node according to claim 2, further comprising: a WWAN transmission unit that transmits the WWAN hierarchical modulation signal to the interface node via a first communication path and transmits the WWAN hierarchical modulation signal to the base station via a second communication path. Receiving a wireless wide area network (WWAN) hierarchical modulation signal transmitted from a user equipment (UE) device and comprising a low modulation order component and a high modulation order component;
Demodulating the high modulation order component to recover the high modulation order component data;
A method of transmitting the high modulation order component data to the WWAN. The low modulation order component corresponds to a first service level data signal;
14. The method of claim 13, wherein the high modulation order component corresponds to a second service level data signal.   14. The method of claim 13, wherein the transmitting comprises transmitting the high modulation order component data to the WWAN when a base station in the WWAN is unable to recover the high modulation order component data from the hierarchical modulation signal.   16. The method of claim 15, wherein the transmitting comprises wirelessly transmitting the high modulation order component data to the base station via a WWA radio channel.   14. The method of claim 13, wherein transmitting comprises transmitting the high modulation order component data to the WWAN if it is determined that a signal to noise ratio of the WWAN hierarchical modulation signal received at the base station is lower than a threshold.   The method of claim 13, wherein the transmitting includes transmitting the high modulation order component data over a wired communication network.   The high modulation order component is modulated by a modulation selected from the group consisting of QPSK, 16-QAM, 64-QAM, and 256-QAM, and the low modulation order is BPSK, QPSK, 16-QAM, and 64- 14. The method of claim 13, modulated by a modulation selected from the group consisting of QAM.   15. The method of claim 14, wherein the first service level data is real-time data and the second service level data is delay tolerance data.

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