KR100886285B1 - Efficient Paging in Wireless Communication Systems - Google Patents

Abstract

A method and apparatus for efficient two stage paging of a wireless communication system is disclosed. The wireless terminal is assigned to a paging group. Several first paging message information bits are modulated into a first paging signal (using asynchronous modulation) and passed from the base station to the wireless terminal. The WT wakes up to receive the first paging signal and quickly determines whether the paging group should expect the second paging signal, and if so, the WT operates to receive the second paging signal, otherwise the WT Goes back to sleep to conserve power. The base station modulates the plurality of second message information bits into a second paging signal (using synchronous modulation) and sends the signal to the WT. The WT may be determined to be a paged WT from the information of the first and second paging signals and process the paging command. The paged intended WT may send an acknowledgment signal on the dedicated uplink resource.

Description

Efficient PAGING IN A WIRELESS COMMUNICATION SYSTEM}

TECHNICAL FIELD The present invention generally relates to the field of paging in wireless communication systems, and more particularly to improved methods and apparatus for efficient two stage paging.

In wireless communication systems, the concept of sleep state and paging is important to provide network connectivity for large scale wireless devices, for example wireless terminals, in a battery power efficient and wireless link resource efficient manner. Wireless terminals may be implemented in various mobile devices.

The sleep state provides an operating mode that minimizes battery power consumption to the wireless device by shutting down all or part of the transmit / receive circuitry of the terminal. In addition, in some systems, a dedicated wireless link resource is not allocated to the wireless terminal in the sleep state, so that a large number of users can be simultaneously supported. During a time when there is no traffic activity on the wireless terminal, the wireless terminal may sleep to conserve resources.

Paging involves periodically waking the wireless device from sleep and operating the wireless terminal to receive and process a paging message (if transmitted) in the downlink, for example, in communication from the base station to the wireless terminal. The base station usually knows when the wireless terminal should wake up. Therefore, if the base station wants to contact or page the wireless terminal, the base station may transmit a paging message in the downlink paging (DLPG) channel when the wireless terminal wakes up and monitors the channel. If the wireless terminal does not receive any message about it in the DLPG channel, the wireless terminal may go back to sleep. Otherwise, the wireless terminal must perform any action specified in the paging message. For example, the wireless terminal may receive the message and return to the sleep state. Alternatively, the wireless terminal may access the base station to establish an active connection with the base station.

The time interval between two consecutive wakeup periods is called the paging cycle. This is during part of a paging period in which the wireless terminal does not perform processing related to the receipt of a page that may operate in a sleep state. In order to maximize the benefit of the sleep state, known paging systems generally use large values for paging cycles. For example, a typical paging period in a voice system, for example IS-95, is about 1 to 3 seconds. In a data system, the paging period can be much larger. For example, a typical paging period at 1 × EV DO is about 5 seconds. In known systems, in order to receive a DLPG channel when the wireless terminal wakes up, the wireless terminal typically needs to perform specific physical layer operations such as synchronization of the downlink signal and the receiver and channel estimation practice for the downlink channel. In addition, DLPG channel transmissions typically take a relatively long period of time and typically include short indication messages as well as identification information. For example, paging message transmission in an IS-95 system may occupy 80 ms. Therefore, a wireless terminal typically consumes a significant amount of battery power during each period in which a page can be received when waking up, for example to complete all the operations required for a device operating at full power of 80 kHz or more. This known paging method is well suited for establishing an end-to-end setup for conventional communication services such as voice channels that have a relatively long duration and can support a moderate amount of delay between paging periods, for example a few seconds.

However, a large paging cycle (which conserves power) increases the paging latency, which is not suitable for many emerging services such as push-to-talk. New services may require very short paging latency, for example a period of one second or less, which gives the user an immediate response. For example, the preferred paging period for minimizing call setup time in a push-to-talk system may be about 100 ms, which is much shorter than many known paging systems can support. Note that in known paging systems such as those used in IS-95, it is not desirable for these systems to simply be able to dramatically reduce paging cycles in order to meet these requirements. This is partly due to the significant amount of battery power consumption required for each wakeup period of the known paging system due to the channel estimation process. If a small paging cycle is used in such a system, it is not practical for the user to replace the device's battery very often because of the amount of power consumed due to frequent wakeup operations. Therefore, there is a need for an efficient paging system that can meet the short paging latency requirements of emerging services. It would be highly desirable if short paging latency could be achieved without significantly increasing overall battery power consumption compared to conventional devices.

Based on the above description, improved paging to increase the paging efficiency of the wireless communication system to meet the low paging latency requirements of emerging services such as push-to-talk and / or to reduce battery power consumption of existing services. It is clear that there is a need. A new paging method that reduces the battery power consumption of the wireless terminal takes advantage of repetitive opportunities of failed paging attempt pages, and / or limits system interference due to paging signaling. Paging improvements developed to meet emerging service requirements can also be used to benefit existing traditional service system applications, increasing overall efficiency and conserving resources, and need not be limited to applications requiring or using low latency paging. .

The present invention relates to a paging method and apparatus. The method and apparatus of the present invention can be used to reduce wireless terminal, eg mobile device power consumption requirements, associated with paging compared to known paging techniques.

According to the present invention, pages are transmitted using a plurality of signals. The first paging signal is used to indicate whether a paging message is being sent to a particular wireless terminal or group of wireless terminals, for example. When the first paging signal indicates that a paging message is being sent, at least one additional paging signal, for example a second paging signal, is sent. In most cases, the second paging signal is transmitted after a first paging signal, for example at a fixed time offset from the first paging signal.

In various embodiments, the first paging signal is configured to decode channel estimation information for decoding so that a page is being transmitted to a wireless terminal or to a device within a group to which a particular wireless terminal belongs, without the wireless terminal having to perform a channel estimation operation. It is sent using a modulation type that is not needed. The second paging message is typically sent using a modulation method different from the first modulation type, for example using a modulation method that uses channel estimation information in the demodulation process.

In some embodiments, the first paging signal is transmitted using a non-coherent modulation type, such as on / off modulation, quadrature modulation, and differential modulation. In this embodiment, the second paging signal is transmitted using coherent modulation. Examples of synchronous modulation include quadrature phase shift keying and quadrature amplitude modulation. Asynchronous modulation techniques do not require channel information to decode the modulated signal. Accordingly, an asynchronous modulated signal can be decoded quickly without having to spend time finding and / or using channel information, usually in a decoding process. Synchronous modulation techniques use channel information for decoding the modulated signals. Accordingly, although often supporting higher coding rates than asynchronous modulation techniques, synchronous modulation needs to spend time acquiring accurate channel estimates and / or other channel information before the device can reliably decode the synchronously modulated signal. There may be.

In some but not all embodiments, the first paging signal includes fewer information bits than the second paging time signal. The first paging signal may be transmitted at a predetermined, for example periodic time, and has a known relationship for a particular wireless terminal or group of wireless terminals. As such, by waking up at a predetermined time, the mobile terminal can receive and decode the first paging signal. If the first paging signal indicates, for example, that the paging message has been sent as a second paging signal or using multiple additional paging signals, then the mobile device wakes up and sends a second paging signal that includes all or part of the paging message. Generates essential channel information that can be used to decode.

When the first paging signal indicates page transmission to at least one device in a group of wireless terminals, the second paging signal may be used alone or in combination with information of the first paging signal so that any of the groups to which the first paging signal corresponds. Enough information to determine if a paging message sent to a particular wireless terminal is intended. In some embodiments, the second paging signal includes all or part of a wireless terminal identifier used to identify the wireless terminal as a sector, cell or system to which a particular second paging signal is sent.

The paging signal, for example the first and second paging signal, may be transmitted periodically, for example according to a known predetermined schedule. If the particular first paging signal indicates that there is no paging message being transmitted, the second paging signal transmission slot associated with the particular first paging signal may not be used.

One or more paging signals modulated with the synchronous modulation method may be associated with a first paging signal modulated with the asynchronous modulation method. This embodiment is particularly suitable for implementations in which a number of wireless terminals, for example a group of terminals, are associated with a particular first paging signal.

Other embodiments may have different types of paging periods and / or paging intervals.

The method and apparatus of the present invention can be used in many different types of communication systems, including CDMA and OFDM systems.

Numerous additional features, advantages and embodiments of the method and apparatus of the present invention are described in the following detailed description.

1 illustrates an exemplary wireless communication system that may utilize the paging method of the present invention.

2 illustrates an exemplary base station implemented in accordance with the present invention.

3 illustrates an exemplary wireless terminal implemented in accordance with the present invention.

4 illustrates an exemplary downlink first and second paging signal in accordance with the present invention.

5 illustrates exemplary downlink first and second paging signals illustrating information conveyed in accordance with the present invention.

6 illustrates downlink two-stage paging signaling of an exemplary embodiment using eight paging groups in accordance with the present invention.

7 illustrates downlink two-stage paging signaling of another exemplary embodiment using eight paging groups in accordance with the present invention.

8 illustrates downlink two-stage paging signaling of another exemplary embodiment using four paging groups in accordance with the present invention.

9 illustrates the timing relationship between downlink two-phase paging signaling, acknowledgment uplink signaling, and signaling of FIG. 8 in accordance with the present invention.

10 illustrates an exemplary on / off asynchronous modulation scheme that may be used for the first paging signal in accordance with the present invention.

11 illustrates another exemplary asynchronous modulation scheme (using on / off keying and quadrature phase modulation) that can be used for the first paging signal in accordance with the present invention.

12 illustrates an exemplary method of operating a base station and generating a paging signal in accordance with the present invention.

13 illustrates an exemplary method of operating a wireless terminal to receive and process a paging signal in accordance with the present invention.

1 illustrates an exemplary wireless communication system 100 implemented in accordance with the present invention. Exemplary wireless communication system 100 is a spread spectrum OFDM (Orthogonal Frequency Division Multiplexing) multiple access system. Although an exemplary OFDM wireless communication system is used in the present application for the purpose of describing the present invention, the present invention is broader in scope than the example and can be applied to many other communication systems, such as CDMA wireless communication systems, as long as paging is employed. have.

System 100 includes a number of cells: cell 1 102, cell M 104. Each cell (cell 1 102, cell M 104) includes a base station (BS) (BS 1 106, BS M 108), respectively, and represents a radio coverage area of the base station. BS 1 106 is connected to multiple end nodes EN (1) 110 and EN (X) 112 by radio links 114 and 116, respectively. BS M 108 is connected to multiple end nodes EN (1 ') 118 and EN (X') 120 by radio links 122 and 124, respectively. End nodes 110, 112, 118, and 120 may be mobile and / or fixed wireless communication devices, referred to as wireless terminals (WTs). Mobile WTs are sometimes referred to as mobile nodes (MNs). MN travels throughout system 100. BS 1 106 and BS M 108 are connected to network node 126 by network links 128 and 130, respectively. Network node 126 is connected to other network nodes and the Internet by network link 132. The network links 128, 130, 132 may be optical fiber cables, for example.

The paging method of the present invention may be used in the exemplary OFDM wireless communication system 100. Each base station (e.g., BS 1 106) is an EN (e.g., EN (1) 110) in a cell in which the BS is located (e.g., cell 1 102) in accordance with the present invention. Transmit paging signal information including, for example, a first paging signal using asynchronous modulation, and a second paging signal using, for example, synchronous modulation. The EN (eg, EN (1) 110) receives paging information and responds by, for example, sending one or more acknowledgment signals in accordance with the method of the present invention.

2 illustrates an exemplary base station 200 implemented in accordance with the present invention. BS 200 is a more detailed representation of BS 200 that may be used as one of BSs 106 and 108 of system 100 shown in FIG. Exemplary BS 200 includes receiver 202, transmitter 204, processor 206, I / O interface 208, and memory 210, interconnected by a bus 212 through which various elements exchange data and information. ). The transmitter 204 includes a first modulation module 220 and a second modulation module 222. Receiver 202 is coupled to antenna 214 where BS 200 receives a signal from wireless terminal 300 (see FIG. 3). The received signal may comprise, for example, an acknowledgment message signal sent by the WT in response to the paging message. The transmitter 204 is coupled to an antenna 218 through which the BS 200 can transmit information including the paging message signal to the plurality of WTs 300. I / O interface 208 provides an interface from BS 200 to the Internet and other network nodes.

Memory 210 includes routine 224 and data / information 226. The processor 206, for example the CPU, executes the routine 224 and uses the data / information 226 in the memory 210 to control the BS 200 and to perform routine base station operations, e.g., wireless to the user. Scheduling of link resources, downlink traffic channel tone hopping sequence control, transmitter 204 power control for the downlink traffic channel, and the like, implements the paging method of the present invention. The routine 224 includes a communication routine 228 and a base station control routine 230. Base station control routine 230 includes scheduler module 232, signaling routine 234, and timing module 236. The signaling routine 234 includes a first paging signal module 238, a second paging signal module 240, and an acknowledgment signal module 242.

Data information 226 includes data 244, first paging signal system information 246, second paging signal system information 248, paging request 250, first paging signal message 252, second paging signal Message 254, acknowledgment message 256, paging signal power information 258, and wireless terminal data / information 260. The data 244 can include data to be sent to the WT 200 (eg, user data from a communication session with a peer node) and / or data received from the WT 300.

The wireless terminal (WT) data / information 260 includes WT data / information for each of the plurality of wireless terminals 1... N, for example WT 1 information 282, WT N information 284. . The WT 1 information 282 includes data 286, terminal identification (ID) information 288, internet protocol (IP) address information 290, paging information 292, and mode information 294. Data 252 may include data intended to be received by BS 200 and delivered to WT 1 and data received from WT 1 and intended for a peer node of WT 1, eg, WT N. The terminal ID information 288 may be a base station allocation ID for WT 1. The IP address information 290 may be an identifier unique to the WT 1 300 or may be independent of the base station. Paging information 292 includes first paging signal information 296, second paging signal information 298, and paging acknowledgment information 299. The first paging signal information 296 may include information that defines and / or includes a first paging signal message 252 scheduled for WT 1, the information corresponding to a group in which WT 1 is a member. It may include an ID. The second paging signal information 298 may include information that defines and / or includes a second paging signal message 254 scheduled for WT 1, the information uniquely identifying WT 1, the WT Additional paging information such as timing information, transmission power level, and page type regarding when to send the second paging message for 1 may be included. The paging acknowledgment information 299 may include information indicating whether an acknowledgment message 256 from WT 1 has been received in response to the second paging signal message 254 sent from the BS 200. The mode information 294 may designate a state of the WT 1 (eg, an ON state, a sleep state, and the like).

The first paging signal system information 246 includes tone information 262, modulation information 264, first paging information bits 266, WT related information 268, and timing information 270. Tone information 268 defines the tone to be used for the first paging signal. Tone information 268 may define a subset of tones. In some embodiments, each tone subset may comprise a contiguous physical tone, and the first paging signal is transmitted at transmit power applied to one tone subset, while no transmit power is applied to the other tone subset. By using a subset of consecutive tones that contain several tones, assuming that the channel does not change too much between the tones of the subset, then in any case where asynchronous modulation is used, data may be recovered for the tones without channel estimation. . The modulation information 264 controls the operation of the first modulation module 220 in accordance with the present invention to modulate the information of the first paging signal message 252 and to select the asynchronous modulation scheme (s) for transmitting the first paging signal. It may include information used by the first paging signal module 238 to implement the. Exemplary asynchronous modulation schemes may include on / off modulation, quadrature modulation, and differential modulation. The implemented asynchronous modulation scheme may use code words and may use phase information as well as amplitude information depending on the asynchronous modulation scheme used. The first paging information bit 266 includes the information bits of the first paging signal message 252. The first paging information bit 266 may include a group identification (ID) bit and an extension bit. The group ID bit may comprise a number of bits of the first paging signal message 252 that may be modulated to convey if any particular group has a member being paged by the first paging signal message 252. . The extension bit may include bits that may be set in the first paging signal message 252 to indicate that the WT in the group with the page should normally look for the second paging signal message 254 at a time associated with another group. . The extension bit can be used when multiple WTs in a single group need to be paged at the same time, and the second paging signal message 254 normally used at a predetermined time does not have sufficient capacity to convey information. The WT related information 268 may associate each individual WT with which the BS 200 may receive a page (e.g., a WT with a unique IP address 290) to the group identified by the group ID bit. Include information to make it available. The timing information 270 includes information defining when to send the first paging signal message 252 to the WT. For example, timing information 270 may include a super slot for transmitting a first paging message signal, a paging interval segment (e.g., a repetition period between successive first paging signals), a paging interval (e.g., paging) Repetition interval between two consecutive wakeup periods for a group) and / or specific OFDM symbol period (s) within a beacon slot used for transmission timing control of the first paging signal. Since the WT battery power consumption is very small in each wake-up period, in the present invention, the paging system employs a relatively small paging cycle, for example, about 100 ms, to reduce the paging waiting time and at the same time lower the overall battery power consumption of the WT. I can keep it.

The second paging signal system information 248 includes tone information 272, modulation information 274, second paging information bits 276, WT identification information 278, and timing information 280. Tone information 272 may comprise a set of tones defined to be used for transmission of the second paging message. In some embodiments, the tones used may follow the hopping sequence. The modulation information 274 controls the operation of the second modulation module 222 to modulate the second paging information bits 276 of the second paging message 254 into a second paging signal. It may include information used in the asynchronous modulation scheme (eg, quadrature phase shift keying (QPSK) or quadrature amplitude modulation (QAM)) used by. The second paging information bits 276 may include bits used to convey additional information, such as bits used for paging identification and information providing a specific paging command to the paged WT 300. Examples of commands that may be delivered by the second paging message include transition to the on state, reception of timing control information, transmission of timing control information, transmission of power control information, transmission of status information, and the like. The second paging information bit 276 includes a larger number of bits than the first paging information bit 266 in accordance with the present invention. The WT identification information 278 may include information that allows the WT 300 to receive the second paging information to confirm that it is the particular receiving side intended for the second paging signal message 254. In some embodiments, WT identification information 278 includes a full WT identifier sufficient to uniquely identify the intended receiving party to the cell. In some embodiments, identification information 278 includes enough bits to convey a complete IP address (eg, IP address information for WT1 290). In another embodiment, the WT identification information 278 may include a partial identifier such that the information of the identification bits from the second paging message 254 is carried by the group identification bits of the second paging signal message 252. When combined with the information, the complete IP address of the intended recipient of the second paging message 254 can be determined. The timing information 280 may include information about when to send a second paging message to the WT. For example, different groups may be assigned to different OFDM symbol times within a super slot, paging interval segment, paging interval, and / or beacon slot to which the BS 200 will transmit the second paging message 254 signal. Each group may be assigned to several consecutive OFDM symbol times within the paging interval for the second paging signal message 254 signal. Paging request 250 is generated by BS 200 or received by BS 200 from another element in the system, such as another base station, AAA (authentication, account management, authorization) server, peer node, or the like. It includes a page request for a specific wireless terminal. The first paging signal message 252 is a message to be sent to the WT 300 carrying the first paging information bit 266. The first paging signal message 252 is modulated using a first paging asynchronous modulation scheme in accordance with the present invention. The second paging signal message 254 is a message to be sent to the WT 300 carrying the second paging information bit 276, which message 254 is modulated using a second paging synchronous modulation scheme in accordance with the present invention. do. Acknowledgment message 256 is a message received from WT 300. The acknowledgment message 256 is sent by the WT 300 to the BS 200 in response to successful receipt of the second paging signal message 254 intended for the particular WT 300. Acknowledgment message 256 may be a short message (eg, one or several bits) and is sent at a predetermined time (eg, at a constant time offset for the second paging signal message). In some embodiments, acknowledgment message 256 may be scheduled to be received by BS 200 before a designated time for the next potential second paging signal message. This enables retransmission of the second paging message based on the notified decision when no acknowledgment is received and the paging period is not skipped. The paging signal power information 258 may include information defining power levels of the first and second paging signals. In some embodiments, the power level of the second paging signal may vary as a function of the number of unsuccessful page attempts, page type, service level, and / or mode 294. For example, when the first second paging signal message 254 signal is sent by the BS 200 to the WT 300, the power level may be set to a low level. If acknowledgment 256 is not received, the power level rises and the same second paging signal may be sent back to the same WT terminal at the time reserved for the second paging message. In some embodiments, a repeating second paging message 254 is sent (at an elevated power level) in the next valid second paging time slot. In another embodiment, a recurring second paging message 254 is sent (at an elevated power level) at the standard time of the next paging interval scheduled for the second paging message 254 intended for the group to which the WT 300 belongs. do.

The communication routine 228 implements various communication protocols used by the base station 200. Base station control routine 230 controls the functional operation of the base station, including the operation of receiver 202, transmitter 204, user scheduling, power control, timing control, and paging signaling in accordance with the present invention. Base station control routine 230 includes scheduler module 232, signaling routine 234, and timing module 236. The scheduler module of the base station schedules the WT 300 for uplink and downlink radio link resources (eg, bandwidth over time). The signaling routine 234 uses the data / information 226 to send the signal (including the first paging signal message 252 and the second paging signal message 254) to the WT 300. Operate the receiver 202 to control the operation of and to receive a signal (including the acknowledgment message 256) from the WT 300. The timing module 236 uses the data / information 226 including the first paging signal timing information 270 and the second paging signal timing information 280 to determine the first and second paging messages 252, 254. Control the transmission timing. The first paging signal module 238 uses the data / information 226 including the paging request 250, the first paging signal system information 246, and the WT data / information 260 to determine the first paging signal message ( 252, generate a first paging signal message 252 by controlling the first modulation module 220, and control the first modulation module 220 to perform asynchronous modulation of the first paging signal message 252. The transmitter 204 is controlled to transmit the modulated signal to the WT 300. The second paging signal module 240 may include data / information 226 including the paging request 250, the second paging signal system information 248, the page signal power information 258, and the WT data / information 260. Generate a second paging signal message 254, control the second modulation module 222 to perform synchronous modulation of the second paging signal message 254, and control the transmitter 204 to generate a modulated signal. Send to the WT 300. In some embodiments, the second paging signal module 240 may be activated by the paging request 250 and the second paging signal module is not activated when there is no paging request in progress. Acknowledgment signal module 242 controls receiver 202 to process acknowledgment message 256 received from WT 300 in response to second paging signal message 254. Acknowledgment signal module 242 forwards paging acknowledgment message 256 to paging acknowledgment information 299 of WT data / information 260, which is, for example, a second paging signal message at a higher signal power level. It is used to determine whether retransmission of 254 is necessary.

3 illustrates an exemplary wireless terminal (end node) 300 implemented in accordance with the present invention. Exemplary WT 300 may be used with any one of the WTs 110, 112, 118, 120 of system 100. Exemplary wireless terminal 300 includes a receiver 302 coupled to an antenna 312, a transmitter 304 coupled to an antenna 318, a processor 306, and a memory 308, which are various elements of data / information. It is connected to each other by a bus 310 that can exchange the.

Receiver 302 receives a downlink signal comprising first and second paging signals from BS 200 in accordance with the present invention. Receiver 302 includes a first demodulation module 314 and a second demodulation module 316. The first demodulation module 314 demodulates the received first paging signal (sent from the BS 200) according to the asynchronous modulation scheme employed in accordance with the present invention. The second demodulation module 316 demodulates the received second paging signal (sent from the BS 200) according to the synchronous modulation scheme employed in accordance with the present invention.

Transmitter 304 is used to transmit an uplink signal to BS 200. The transmitted uplink signal includes an acknowledgment signal responsive to the received paging message (eg, each acknowledgment corresponds to a received second paging signal intended for the WT 300).

Memory 308 includes routine 322 and data / information 324. The processor 306, for example the CPU, executes the routine 322 and uses the data / information 324 in the memory 308 to control the WT 300 and to perform routine wireless terminal operation (eg, downlink). Receiving traffic channel information, transmitting uplink traffic channel information, performing a WT power control operation, performing a WT timing control operation), and implementing the paging method of the present invention. The routine 322 includes a wireless terminal control routine 328 that includes a communication routine 326 and a signaling routine 330 and a timing module 332. The signaling routine 330 includes a first paging signal detection module 334 and a second paging signal detection module 336. Data / information 324 includes data 338, first paging signal system information 340, second paging signal system information 342, received first paging signal message 344, received second paging signal message. 346, paging acknowledgment message 348, and WT information 350. The data 338 may include data to be transmitted to the BS 200 (eg, user data intended for a peer node in a communication session with the WT 300) and data received from the BS 200.

The first paging signal system information 340 includes tone information 352, modulation information 354, first paging information bits 356, WT related information 358, and timing information 360.

The tone information 352 may define a tone to be used for the signal corresponding to the received first paging signal message 344. Tone information 352 may define a subset of tones. In some embodiments, each tone subset may comprise a contiguous physical tone, and the first paging signal is transmitted by the BS 200 at transmit power applied to one tone subset while transmitting to the other tone subset. Power is not applied When using a subset of consecutive tones, one can assume that the channel does not change too much between the tones of the subset. In this case, it may be possible for the WT 300 to restore the transmission data included in the received first paging signal message 344 without channel estimation depending on the modulation scheme and the channel state.

The modulation information 354 is configured to process the first paging signal using one or more asynchronous modulation scheme (s) selected in accordance with the present invention and to obtain information of the received first paging signal message 344. ) May include information used by the first paging signal detection module 334 to control the operation. In performing asynchronous demodulation, the WT 300 may or may not need to set channel estimates or rely on channel condition history to demodulate and recover the transmitted information. Exemplary asynchronous modulation schemes may include on / off modulation, quadrature modulation, and differential modulation. The implemented asynchronous modulation scheme may use code words and may use phase information and / or amplitude information.

The first paging information bit 356 includes the information bits of the received first paging signal message 344. The first paging information bits 356 may typically include one or more group ID bits and, optionally, extension bits. The group ID bit indicates if any particular group has a member being paged by the first paging signal message 344 received. The group ID bit may be a set of mask bits corresponding to a preselected number of bits used at the beginning of each WT identifier assigned to the WT of the group, for example, the first n bits of the IP address assigned to the WT of the group. As such, in this embodiment the group ID bits may be a preselected number of bits, each group ID bit set being a unique pattern of a preselected number of bits, e.g., a mask bit set, at the beginning of the WT identifier, Each mask bit corresponds to a unique pattern (for other group ID bits) of the first n bits of the WT IP address. The extension bits may include bits that may be set in the first paging signal message to indicate that the WT 300 in the group should normally look for a second paging signal message at a time associated with another group. The extension bit can be used when multiple WTs 300 in a single group need to be paged at the same time, and the second paging message normally used at a predetermined time does not have sufficient capacity to convey information.

WT related information 358 includes information relating WT 300 to a group identified by a group ID bit set. The timing information 360 may include information defining when to find the first paging message signal from the BS 200. For example, in some embodiments, timing information 360 may include a superslot for transmitting the first paging message, a paging interval segment (or a repetition period between successive first paging signal messages 252), a paging interval ( Repetition interval between two consecutive wakeup periods for a paging group) and / or specific OFDM symbol period (s) within a beacon slot used for transmission timing control of the first paging signal.

The second paging signal system information 342 includes tone information 362, modulation information 364, second paging information bits 366, WT identification information 368, and timing information 370. Tone information 362 includes a set of tones defined for use in processing the received second paging message signal to extract the received second paging signal message 346. In some embodiments, the tones can follow a hopping sequence.

The modulation information 364 is a synchronous modulation scheme used to demodulate the second paging message signal into the received second paging signal message 346, eg, quadrature phase shift keying (QPSK) or quadrature amplitude modulation (QAM). Contains information used for The second paging signal message 346 includes a second paging information bit 366.

The second paging information bits 366 are bits used for paging identification in accordance with the present invention and / or specific paging commands to the paged WT 300, e.g., transitioning to an on state, receiving timing control information, timing control. And bits used to convey additional information such as information providing information transmission, power control information transmission, status information transmission, and the like. The second paging information bit 366 includes a larger number of bits than the first paging information bit 356 in accordance with the present invention. The WT identification information 368 may include information that allows the WT 300 to receive the second paging information to confirm that it is the particular receiving side intended for the received second paging signal message 344. This WT identification information 368 may include a complete identifier that uniquely identifies the WT in the cell in which the WT is located and / or in the system 100. In some embodiments, identification information 368 includes enough bits to carry the complete IP address. In another embodiment, the WT identification information 368 includes a partial identifier such that the information of the identification bit from the received second paging message 346 is applied to the bit or bits of the received first paging signal message 344. In combination with the information conveyed by the full unique identifier of the intended receiving side of the received second paging message 346, eg an IP address, may be determined. The determined IP address can usually be compared to the IP address 376 of the WT 300 for matching.

The timing information 370 includes information indicating when to find a second paging message signal from the BS 200. For example, a group corresponding to the WT 300 may be assigned several consecutive OFDM symbol times within the paging interval in which they must find the second paging signal and capture the received second paging signal message 346.

The received first paging signal message 344 is a message obtained from the received first paging signal (sent from BS 200) carrying the first paging information bit 356. The received first paging signal message 344 is sent to the WT 300 by controlling the operation of the first demodulation module 314 using the first paging signal detection module 334 to demodulate the received first paging signal. Is obtained. The decoding of the first paging signal follows the asynchronous modulation scheme used for the modulation of the first paging signal.

The received second paging signal message 346 is sent from the second demodulation module 316 using the second paging signal detection module 336 to demodulate the received second paging signal (sent from the BS 200). This is a message obtained by the WT 300 by controlling the operation. The second paging signal is decoded according to the synchronous modulation scheme used for modulation of the second paging signal. As such, the first and second paging signals are demodulated in accordance with the present invention.

The received second paging signal message carries a second paging information bit of the second paging information bit 366. The paging acknowledgment message 348 is generated by the WT 300 and sent to the BS 200 in response to successful receipt of the second paging signal message 254 intended for the particular WT 300 generating the acknowledgment. Message. The paging acknowledgment message 348 can be a short message (e.g., one or several bits), which is transmitted at a predetermined time (e.g., for a second paging signal message), and the second paging transmitted. A dedicated (reserved) radio link resource (eg, one tone symbol) corresponding to the message may be allocated. The timing agreement between the BS 200 and the WT 300 in relation to the paging signal and the acknowledgment signal may follow a known schedule or agreed methodology known to both the BS 200 and the WT 300.

The WT information 350 includes data 372, terminal ID information 374, IP address information 376, received paging information 378, and mode information 380. The data 372 may include data to be transmitted to the BS 200 (eg, user data to be delivered to a peer node) and data received from the BS 200. The terminal ID information 374 may be an identifier for the WT 300 assigned by the BS 200. IP address information 290 may be an identifier unique to WT 300 or may be independent of a base station. The received paging information 378 includes first paging signal information 382 and second paging signal information 384. The first paging signal information 382 may include information contained in the received first paging signal message 344 intended for the WT 300, including the group ID for which the WT 300 is a member of the group. . The second paging signal information 384 may include information for uniquely identifying the WT 300 in the cell and / or system 100 in the received second paging signal message 346 intended for the WT 300. The included information may include additional paging information having a type corresponding to the type of information included in the page, such as the page type.

The communication routine 326 implements various communication protocols used by the wireless terminal 300. The wireless terminal control routine 330 controls the functional operation of the wireless terminal, including the operation of the receiver 302, the transmitter 304, power control, timing control and paging signaling in accordance with the present invention. The signaling routine 330 uses the data / information 324 to control the operation of the receiver 302 to receive and process a signal (including the first paging signal message and the second paging signal message) from the BS 200. And operate transmitter 304 to send a signal (including paging acknowledgment message 348) to BS 200. The timing module 332 activates the WT using the data / information 324 including the first paging signal timing information 360 and the second paging signal timing information 370 to enable the first in a sleep state at the appropriate time. Receive a paging signal, return to sleep at an appropriate time, receive a second paging signal at an appropriate time, and send an acknowledgment message 348 at an appropriate time. The first paging signal detection module 334 controls the receiver 302 to receive the first paging signal using data / information 324 including the first paging signal system information 340 and the WT information 350. And control the operation of the first demodulation module 314 to restore the first paging signal message 344 by, for example, performing asynchronous demodulation of the received first paging signal. The first paging signal detection module 334 also uses the first paging signal information 382 corresponding to the first paging information bit 356 from the first paging signal message 344 received using the data / information 324. And determine whether the WT 300 is a member of the group intended to be the receiving side of the page, and take appropriate action (e.g., to activate the transition back to sleep or to activate the first paging signal detection module). 336.) The second paging signal detection module 336 receives the second paging signal using data / information 324 including the second paging signal system information 342 and the WT information 350. Control the receiver 302 and control the second demodulation module 316 to demodulate the received second paging signal into a received second paging signal message 344. The second paging signal detection module uses the data / information 324 to determine whether the WT 300 is the intended receiving side of the page. If the WT 300 is the receiving side, information corresponding to the second paging information bit 366 in the received second paging message 346 is transferred to the WT second paging signal information 384, and the timing module 332 The paging acknowledgment signal message 348 is generated and transmitted by the transmitter 304 at the appropriate time determined by. The second paging signal detection module also controls the WT 300 to take appropriate action to execute the command passed in the received second paging signal message 346.

4 illustrates signaling for two stage paging and two separate types of paging signals that may be used in the exemplary communication system 100 of one exemplary embodiment of the present invention. 4 is a graph 400 of the frequency of the vertical axis 402 versus the time of the horizontal axis 404. Paging interval 418 represents the time between successive first paging signals 406 and 410. Paging interval 418 includes a first paging signal 406 followed by a second paging signal 408. The first paging signal 406 occupies a very short duration 414 (eg, one OFDM symbol) and uses an asynchronous modulation scheme. The second paging signal 408 occupies a small number of OFDM symbols 416 (e.g., less than 10) to minimize the processing cost of receiving the channel and employ an asynchronous modulation scheme. The first paging interval 418 is followed by a second paging interval that includes a first paging signal 410 and a second paging signal 412.

The first paging signal 406 carries one bit of information, which indicates whether a user (eg, WT 300) or generally a group of users is being paged. If the information bit of the first paging signal 406 is zero, no user is being paged. If the first paging signal information bit is 1, at least one user in the group is being paged. The operation of the user WT 300 includes two steps. When the user WT 300 wakes up, the user WT 300 first receives a first paging signal 406. When the user detects that the first paging signal 406 information bit is zero, the user (WT 300) returns to the sleep state. Otherwise, the user WT 300 continues to receive the detailed paging message of the second paging signal 408. The second paging signal 408 may include detailed paging information, such as the page type (e.g., whether the user was asked to access the base station or received an additional message on another explicit downlink channel). . Moreover, if a group of users is monitoring a single first paging signal 406, the second paging signal 408 may include a detailed paging identifier of the paged user (s) to identify the group member for whom the page is intended. Can be.

Note that the method can be applied to systems that support the concept of user groups. In particular, a user can be a member of one or multiple user groups. For paging, a user may have his own user paging identifier and may also include a paging identifier for the relevant user group to which the user belongs. In this case, the user will monitor the paging message with his user paging identifier and the associated user group paging identifier. In general, although the user groups are not discussed explicitly below, it is understood that the methods of the present invention can also be applied to paging for user groups.

FIG. 5 illustrates user operations of the two-stage paging method described with reference to FIG. 4. 5 includes a graph 500 as to the frequency of the vertical axis 502 versus the time of the horizontal axis 504. Consider two users WTA1 and WTA2 that monitor the downlink channel assigned to the first paging signal 506. At time t ₁ 515, both WAT1 and WTA2 wake up to receive first paging signal 506. Assume that base station 300 does not page any of these to transmit the first paging signal information bit = 0. After receiving the first paging signal 506, both WAT1 and WTA2 return to sleep. Since the first paging signal information bit is zero, the base station 200 does not transmit the second paging signal (as indicated by dashed box 508). After one paging interval 518, at time t ₂ 519 both WAT1 and WTA2 wake up again to receive another first paging signal 510. Assume that the base station 200 pages WTA1 and sets the first paging signal information bit = 1. Upon reception of the first paging signal 510, both WAT1 and WTA2 continue to receive the second paging signal 512. The second paging signal 512 includes the paging identifier of the user WTA1. Upon receiving the second paging signal 512, the user WTA1 follows the instructions contained in the second paging signal message, if any, and the user WTA2 determines that the identifier of the signal 512 does not match the identifier of the WTA2 and then goes back to sleep. I will go. Note that in the above example, users WAT1 and WTA2 have the same paging interval, but in general different users may have different paging intervals.

The distinction between the first and second paging type signals of FIG. 5 is further described. In FIG. 5, different modulation schemes are used for the first paging type signal, eg, signals 506 and 510, and the second paging type signal, eg, signal 512, according to the present invention. The first paging signal 506 uses an asynchronous modulation scheme that does not require channel information to decode the first modulation type, for example modulated information. WAT1 and WTA2 wake up at the beginning of the first paging signal 506 at time t ₁ 515 to receive one or two OFDM symbols of the first paging signal of duration 514 and process, e.g., For example, an FFT may be performed on one or two received OFDM signals to determine a value of information bits or bits included in the first paging signal. Since the exemplary information bit of the first paging signal 506 is zero, the WT recognizes that there is no corresponding second paging signal 508 and returns to sleep mode at time t ₃ 520 to conserve power. Similarly, the first paging signal 510 uses an asynchronous modulation scheme. WAT1 and WTA2 wake up at or immediately before the start of the first paging signal 506 at time t ₂ 519 to receive one or two OFDM symbols of the first paging signal and process, eg, 1 Alternatively, FFT may be performed on two received OFDM signals to determine an information bit value without requiring channel estimation or other current channel information. Since the information bit of the first paging signal 510 is 1, the WT recognizes that there is a corresponding second paging signal 512 and, in some embodiments, an active state that consumes more power than, for example, the sleep state. Keep it. The second type paging signal 512 uses a modulation scheme that requires the use of channel information to demodulate the modulated information, for example a synchronous modulation scheme. At some time t ₄ 522 before the time t ₅ 524 to start receiving the second paging signal 512, WTA1 and WTA2 start receiving a signal, for example a pilot symbol. During each symbol period, multiple symbols may be transmitted, for example using different tones, but only a few symbols may be pilot symbols at any given symbol time, for example at the time used for symbol transmission. have. In order to obtain accurate estimates for different frequencies, for example tones, several symbol times can be taken to receive a sufficient number of pilot symbols to yield a reliable estimate of the communication channel used to transmit the paging signal. Beginning at t ₄ 522, WTA1 and WTA2 may, for example, perform an FFT on a signal received for four symbol periods before t ₅ 524 to set a reliable channel estimate. The set channel estimate is used in decoding the second paging signal 512 by WTA1 and WTA2.

Time t ₆ 526 is the time when the WT has completed processing of the first paging signal 510. In some embodiments, for example, if WT is still ON, the WT may set the channel estimate using the entire duration from t ₆ 526 to t ₅ 524. However, in some embodiments, the WT goes back to sleep even if information bit = 1 and wakes up again at t ₄ 522 to receive and process sufficient information, for example sufficient pilot signal, so that the channel estimate is set and the second paging. _May be used at t ₅ 524, which is the beginning of signal 512. Wakeup at t ₄ 522 does not occur if the information bit of signal 510 is zero indicating that the second paging signal will not be received. In some embodiments, four pilot symbols are transmitted during one symbol time, and the time interval between t ₄ 522 and t ₅ 524 used to set the channel estimate is 3 to 5 symbol times. In comparison, the first paging signal 506, 510 uses asynchronous modulation that does not require channel estimation to recover the information being conveyed, so that the wireless terminal does not need to wake up before the first paging signal 506, 510. Note the point.

6 shows another embodiment of a two stage paging system of the present invention wherein each first paging signal includes a plurality of information bits, each information bit associated with one second paging group. In one embodiment of Figure 6, each first paging signal carries four information bits. Each of the four information bits specifies whether a user of that user group is being paged, and if so, the corresponding second paging signal to the reserved slot (e.g., using the reserved frequency at a predetermined time). Is sent. The second paging signal of this embodiment includes detailed paging information (eg, paging type and paging identifier corresponding to the paged wireless terminal).

FIG. 6 is a diagram 600 illustrating the frequency of the vertical axis 602 (eg, the tone used in the downlink paging signal) versus the time of the horizontal axis 604. Three exemplary first paging signals 606, 608, 610 and nine exemplary second paging signals 612, 614, 616, 618, 620, 622, 624, 626, 628 are shown in FIG. 6. The first paging signal 606, 610 includes information bits corresponding to the paging groups A, B, C, and D. The first paging signal 608 includes information bits associated with the paging groups E, F, G, and H. Each paging group (A, B, C, D, E, F, G, H) has multiple users (e.g. (WTA1, WTA2), (WTB1, WTB2), (WTC1, WTC2), (WTD1) , WTD2), (WTE1, WTE2), (WTF1, WTF2), (WTG1, WTG2), (WTH1, WTH2)). Beacon slot 650 includes two paging interval segments, namely first paging interval segment (1) 646 and second paging interval segment (2) 648. The first paging interval segment (1) 646 and the second paging interval segment (2) 648 constitute a paging interval 649, which corresponds to the beacon slot 650. Beacon slot 650 has eight super slots: super slot (1) 630, super slot (2) 632, super slot (3) 634, super slot (4) 636, super slot ( 5) 638, super slots 6 and 640, super slots 7 and 642, and super slots 8 and 644. Each super slot, for example super slot (1) 630, represents a repeat time interval for the downlink traffic channel tone hopping sequence. Beacon slot 650 represents a repetitive time interval based on beacon signal transmission from the base station. In this example, beacon slot 650 corresponds to paging interval 649 and includes one for the system that includes paging opportunities for each paging group (A, B, C, D, E, F, G, H). Repetition time interval of the paging signal set. Each paging interval segment 646, 648 represents a time interval associated with one first paging signal and an opportunity for four second paging signals. The paging interval (1) 606 includes a first paging signal (1) 606, a second (group A) paging signal 612, a second (group B) paging signal 614, a second (group C) A paging signal 616 and a second (group D) paging signal 618. The paging interval (2) 648 includes a first paging signal (2) 608, a second (group E) paging signal 620, a second (group F) paging signal 622, a second (group G) A paging signal 624 and a second (group H) paging signal 626.

Paging groups (A, B, C, D) monitor the first paging signal (1) 606, while paging groups (E, F, G, H) monitor the first paging signal (2) (608). Monitor. Paging group A monitors the first information bit of the first paging signal (1) 606, which corresponds to the second (group A) paging signal 612. Paging group B monitors the second information bit of the first paging signal (1) 606, which corresponds to the second (group B) paging signal 614. The paging group C monitors the third information bit of the first paging signal (1) 606, which corresponds to the second (group C) paging signal 616. Paging group D monitors the fourth information bit of the first paging signal (1) 606, which corresponds to the second (group 4) paging signal 618. Paging group E monitors the first information bits of the first paging signal (2) 608, which corresponds to the second (group E) paging signal 620. The paging group F monitors the second information bits of the first paging signal (2) 608, which corresponds to the second (group F) paging signal 622. Paging group G monitors the third information bit of the first paging signal (2) 608, which corresponds to the second (group G) paging signal 624. Paging group (H) monitors the fourth information bit of first paging signal (2) 608, which corresponds to second (group H) paging signal 626.

The operation of the user device (eg, WT 300) is similar to that shown in FIG. 5 for each paging group. An exemplary paging group A is considered to include wireless terminals WTA1 and WTA2. The wireless terminal WTA1 monitors the first information bit of the first paging signal (1) 606. If the first information bit is zero, the wireless terminal WTA1 returns to sleep until the next first paging signal (1) 610. If the first information bit is 1, the wireless terminal WTA1 continues operation to receive the second (group A) paging signal 612. On the other hand, if the first information bit is 0, the base station 200 may suspend transmission of the corresponding second (group A) paging signal 612. If the first information bit is 1, the base station 200 should send detailed paging information in the second (group A) paging signal 612.

One potential drawback of this embodiment is the possible paging delay due to congestion in the individual paging groups. For example, if the base station 200 attempts to separately page multiple terminals belonging to the same paging group (for example, WTA1 and WTA2 of the group A), the base station 200 simultaneously selects the wireless terminals of the paging group. Since only one can page, the base station 200 may take multiple paging intervals (e.g., repeat multiple paging interval segments 1) to page the wireless terminal. Assume that base station 200 attempts to page both wireless terminals WTA1 and WTA2. The paging group A then becomes crowded and pages WTA1 and WTA2 through two iterations of paging interval segment (1) 646. Note that when the paging group is congested, the other paging group is at rest, ie no paging group users are paged out. For example, when the paging group A is congested, the paging group B may be in a stopped state.

The example embodiment described below reduces paging latency by sharing a second paging signal channel between different paging groups. Specifically, one first paging signal includes information bits including a plurality of paging group information bits and extension bits. In Fig. 6, the first paging signal (1) 606 carries four paging group information bits and extension bits (as described above). Similar to the above embodiment, each paging group information bit specifies whether the corresponding paging group user is paged. The user first receives the first paging signal 1. If the corresponding paging group information bit is zero, the user can return to the sleep state. If the corresponding paging group information bit is 1, the user continues to receive the detailed second paging message signal. If the paging group information bit is 1 and the extension bit is 0, the detailed second paging message signal is received in the corresponding second paging signal similarly to the above embodiment. However, if the paging group information bit is 1 and the extension bit is 1, then the detailed second paging message signal corresponding to the user may be transmitted in a second paging signal slot that is different than normally used. In one embodiment, if the paging group information bit = 1 and extension bit = 1, the detailed second paging message signal may be sent in any of four second paging signal channel slots following the first paging signal. In this case, the user continues to receive and process the signal in each of the four second paging signal slots.

Suppose base station 200 wants to page two wireless terminals WTA1 and WTA2 (both in paging group A). The base station 200 sets each paging group information bit of the first paging signal (1) 606 to 0 except for the first paging group information bit set to one. BS 200 also sets the extension bit to 1 in the first paging signal (1) 606. Base station 200 transmits a second paging message signal for WTA1 and WTA2 in any two of four consecutive second paging signal slots corresponding to 612, 614, 616, 618, so that both WTA1 and WTA2 Paging latency can be reduced by enabling paging at the paging interval 1.

In another embodiment, the extension bit = 1 indicates that the WT from the group with group information bit = 1 sends a second paging signal in its group slot or in a slot with group information bit = 0 during its paging period. The WT may use the information in the first paging signal (1) 606 to determine which of the subsequent second paging signals 612, 614, 616, 618 for the candidate paging signal for the WT to receive and process.

7 shows another exemplary embodiment of a two stage paging system according to the present invention. FIG. 7 is a graph 700 illustrating the frequency of the vertical axis 702 (used for the downlink paging signal) versus time on the horizontal axis 704. Two exemplary first paging signals 706, 708 and nine exemplary second paging signals 710, 712, 714, 716, 718, 720, 722, 724, 726 are shown in FIG. 7. The first paging signal 706, 708 includes eight group information bits, one group information bit being identified by each paging group (A, B, C, D, E, F, G, H). Beacon slot 746 has one paging interval 744 and eight super slots: super slot (1) 728, super slot (2) 730, super slot (3) 732, super slot (4) 734, super slots 5 and 736, super slots 6 and 738, super slots 7 and 740, and super slots 8 and 742. Beacon slot 746 represents the repetition time interval of one paging signal set for a system that includes paging opportunities for each paging group (A, B, C, D, E, F, G, H). The paging interval 744 includes a first paging signal (1) 706, a second (group A) paging signal 710, a second (group B) paging signal 712, a second (group C) paging signal ( 714 and second (group D) paging signal 716, second (group E) paging signal 718, second (group F) paging signal 720, second (group G) paging signal 722 And a second (group H) paging signal 724.

The same method described with respect to the four group information bits included in the first information signal (1) 606 of FIG. 6 may be applied to the eight group information bits of the first information signal 706 of FIG. 7. For example, if the first paging signal 706 information bit = 00100010, then the two second paging signals use the second group (C) paging signal 714 and the second (group G) paging signal 722. It is sent to two WTs (e.g., WTC1, WTC2).

In addition, in some embodiments, an extension bit may be added to the eight group information bits of the first information signal 706 using an agreement similar or similar to that described with respect to FIG. 6. For example, if the first paging signal 706 information bit = 00010000, in one embodiment two second paging signals have eight second paging slots 710, 712, 714, 716, 718, 720, 722, 724 Can be transmitted to two members (eg, WTD1, WTD2) of the group D using any two of them.

Consider the example of FIG. 7 in which each wireless terminal specific ID (eg, WT IP address 376) contains 32 bits. In one embodiment, each 32-bit wireless terminal specific ID is 3 bits that designate one of eight groups (A, B, C, D, E, F, G, H) (e.g., by a hash function). ) Can be mapped. The three bits may identify the group to which the base station 200 should deliver the second paging message for the WT 300 and the second normal paging slot that the WT 300 should look for for a potential second paging message. BS 200 may include additional identification information (eg, 29 additional identification information) in a second paging message that may be used for identification of a particular WT 300 intended for the page.

8 shows another exemplary embodiment of a two stage paging system according to the present invention. 8 is a graph 800 illustrating the frequency of the vertical axis 802 (used for the downlink paging signal) versus the time on the horizontal axis 804. Three exemplary first paging signals 806, 808, 810 and nine exemplary second paging signals 812, 814, 816, 818, 820, 822, 824, 826, 828 are shown in FIG. 8. The first paging signal 806, 808, 810 includes four group information bits, one group information bit being identified with each paging group (A, B, C, D). Beacon slot 848 has two paging intervals 846, 846 'and eight super slots: super slot (1) 830, super slot (2) 832, super slot (3) 834, super Slot 4, 836, super slot 5, 838, super slot 6, 840, super slot 7, 842, super slot 8, 844. Beacon slot 848 represents the repetition time interval of two sets of paging signals for a system that includes two sets of paging opportunities for each paging group (A, B, C, D). Paging interval 846 includes first paging signal 806, second (group A) paging signal 812, second (group B) paging signal 814, second (group C) paging signal 816, and A second (group D) paging signal 818. The paging interval 846 'includes a first paging signal 808, a second (group A) paging signal 820, a second (group B) paging signal 822, and a second (group C) paging signal 824 And a second (group D) paging signal 826. In FIG. 8, the repetition time between successive opportunities for a particular (eg group A) second paging group is four super slots, but in FIG. 6 or 7 the repetition interval is eight super slots.

The same method described with respect to the four group information bits included in the first information signal (1) 606 of FIG. 6 may be applied to the four group information bits of the first information signal 806 of FIG. 8. Further, in some embodiments, an extension bit may be added to the four group information bits of the first information signal 806 using agreements similar to or similar to those described with respect to FIG.

The method described with reference to FIG. 8 may be useful in some applications (eg, where minimizing paging intervals for individual WTs 300 is critical and system power can support a significant number of users in each group). It can provide more advantages. In addition, by using the method of FIG. 8, if two members of the same group (eg, group A) require a page (and the implementation does not support extension bits), BS 200 may, for example, Prioritize pages based on queue, quality of service requirements, etc., and then assign those pages to the first paging signal 806 and the second (group A) paging signal 812 to distinguish which pages are more timely. On the other hand, pages with less timeliness can be delayed with the first paging signal 808 and the second (group A) paging signal 820.

9 illustrates exemplary downlink paging signaling, exemplary uplink acknowledgment signals, and timing correlation between signaling in accordance with the present invention. 9 is a diagram illustrating the time on the frequency axis of the vertical axis 902 (e.g., corresponding to the tone used in the downlink paging signal from BS 200 to WT 300) on the horizontal axis 904 (e.g., 900). Three exemplary first paging signals 906, 908, 910 and nine exemplary second paging signals 912, 914, 916, 918, 920, 922, 924, 926, 928 are shown in FIG. 9. The first paging signal 906, 908, 910 includes four group information bits, one group information bit being identified with each paging group (A, B, C, D). Beacon slot 996 has two paging intervals 994, 994 'and eight super slots: super slot (1) 978, super slot (2) 980, super slot (3) 982, super Slots (4) 984, super slots (5) 986, super slots (6) 988, super slots (7) 990, and super slots (8) (992). Beacon slot 996 represents the repetition time interval of two sets of paging signals for a system that includes two sets of paging opportunities for each paging group (A, B, C, D). The paging interval 994 includes a first paging signal 906, a second (group A) paging signal 912, a second (group B) paging signal 914, a second (group C) paging signal 916, and A second (group D) paging signal 918. The paging interval 994 'includes a first paging signal 908, a second (group A) paging signal 920, a second (group B) paging signal 922, and a second (group C) paging signal 924. And a second (group D) paging signal 926.

9 also illustrates the time on the frequency axis of the vertical axis 952 (eg, corresponding to the tone used in the uplink paging acknowledgment signal from the WT 300 to the BS 200) on the horizontal axis 954. Includes a drawing 950. For each second paging signal sent from BS 200 to WT 300, there is a corresponding slot reserved for acknowledgment from WT 300 to BS 200. In an exemplary OFDM system, the dedicated uplink channel resource for each acknowledgment signal may be several tones for several OFDM symbols or one OFDM tone symbol, which is due to the intended receiving side of the corresponding second paging signal. It is reserved for use.

Figure 950 shows nine exemplary acknowledgment signals: (group A) acknowledgment signal 956 (corresponding to second (group A) paging signal 912), (second (group B) paging signal ( (Group B) acknowledgment signal 958, corresponding to 914, (group C) acknowledgment signal 960, (corresponding to second (group C) paging signal 916), and (second (group D) ) (Group D) acknowledgment signal 962 (corresponding to paging signal 918) (group A) acknowledgment signal 964, (corresponding to second (group A) paging signal 920) 2 (group B) paging signal 922 (group B) acknowledgment signal 966, (second C (group C) paging signal 924) (group C) acknowledgment signal 968 ) And (group D) acknowledgment signal 970 (corresponding to a second (group D) paging signal 926).

The first paging signal 906 is synchronized for the super slot 1 (978), the paging interval 994 and the beacon slot 996. The time interval 930 represents the timing relationship between the first paging signal 906 and the second (group A) paging signal 912 slot. The time interval 932 is a delay between the second paging signal slot intervals following the paging interval (eg, the time between the second (group A) paging signal 912 and the second (group B) paging signal 914). Indicates.

9 illustrates an uplink only acknowledgment signal corresponding to a second paging message signal. According to the invention, different users can use the acknowledgment channel over time. For example, during the first paging interval 994, the second (group A) paging signal 912 may be intended for WTA1, and the (group A) acknowledgment signal 956 may be sent by WTA1. Then, during the second paging interval 994 ′, a second (group A) paging signal 920 may be intended for WTA2 and a (group A) acknowledgment signal 964 may be sent by WTA2. Acknowledgment channels, on the other hand, are used in a non-competitive manner.

In Figure 9 the second paging signal and the acknowledgment signal are shown in each of the potential slots. However, if there is no member to be paged at a given paging interval in a particular group, the first paging signal carries that information, and then the corresponding second paging signal and acknowledgment signal will not be transmitted in a predetermined time slot for that given group. will be.

In this particular exemplary embodiment, there is no obvious acknowledgment for the first paging signal. The uplink acknowledgment signal carries one bit information indicating a positive response (indicating a successfully received second paging message) or a negative response (indicating a second paging message received in an invalid state). If the intended receiving side of the second paging signal, e.g., WT 300, does not send an acknowledgment corresponding to BS 200, BS 200 receives that second WP 300 signal is received. We could assume that retransmission of the second paging signal is needed (if the page is still applicable).

After base station 200 transmits a second paging signal (e.g., a second (group A) paging signal 912), base station 200 sends a corresponding uplink acknowledgment signal (e.g., (group A) acknowledgment signal 956) to verify that the paging message was received correctly. If the base station 200 does not receive the acknowledgment, the base station 200 assumes that the paging has not been transmitted and can then retransmit the paging with the second paging signal. If the base station 200 receives a negative response, the base station 200 is notified that the intended receiving side has received the second paging message incorrectly, and the base station may retransmit the paging with a later second message. Given a short paging interval in the present invention, the retransmission latency is also not long. As a result, in some embodiments, the base station may transmit a paging message several times to increase paging reliability.

The time interval 974 represents the delay between the second paging signal and the corresponding acknowledgment signal, eg, the time between the second (group A) paging signal 912 and the (group A) acknowledgment signal 956. Note that the acknowledgment signal 974 precedes the next second paging signal (eg, the second (group B) paging signal 916) by a time interval 976. In some embodiments, BS 200 may retransmit an unacknowledged or negatively responding second paging signal (e.g., if extension bit = 1) to the next available second paging slot. In some embodiments, BS 200 may retransmit a second paging signal that has no response or responds negatively to a next paging interval that includes another first paging signal and another second paging signal.

The paging retransmission mechanism can help reduce the average power required for paging signal transmission. Specifically, when a paging signal is sent to a user who is in a sleep state (eg, WT 300), base station 200 generally does not know the user's downlink channel state. In order to reach a user (e.g., WT 300), the user (e.g., WT 300) often does not require as high a power as the worst case to receive a paging signal, 200) may need to transmit the paging signal using the worst case power. As a paging retransmission mechanism, the base station 200 may transmit a paging signal for the first transmission using relatively little power. If a user (eg, WT 300) is selected at the base station 200, the user (eg, WT 300) may receive a paging signal at a first time, thereby saving downlink power. can do. If the user (eg, the WT 300) is away from the base station 200 and cannot receive the paging signal at the first time, the base station 200 may increase or sometimes increase the power in the second transmission. Can help you reach In general, base station 200 may save transmission power of the downlink paging signal.

In some embodiments, BS 200 may use different power levels for the first and second paging signals. For example, the power level applied to the first paging signal (potentially serving multiple users in multiple groups of users) uses a constant power level in the worst case, while the second paging signal uses various power levels. Can be used. In some embodiments, BS 200 may change the power level of the second paging signal as a function of the number of failed paging attempts. For example, the power level of the second paging signal may be set low in the first attempt. Then, if no acknowledgment is received, the power level may be increased for retransmission of the same second paging signal. As such, the overall level of interference in the system may be reduced. The power level of the second paging signal may also vary as a function of timeliness of the page and / or service level.

Note that because the user receiving the downlink paging signal (eg, WT 300) has just left the sleep state, the user may not be controlled in power or timing. According to the present invention, the uplink paging acknowledgment channel may use a signaling format that does not interfere with other normal data transmissions. In one such embodiment, the uplink paging acknowledgment signal is transmitted in a separate acknowledgment channel that is distinct from normal data transmission in a time division multiplexed (TDM) manner, with each uplink acknowledgment segment being adapted to paging signal transmission in a predetermined manner. Corresponds to the segment of the paging channel used. In addition, a long cyclic prefix is used so that even without timing synchronization, the uplink paging acknowledgment channel is still orthogonal to the uplink access channel. Moreover, because the uplink paging acknowledgment channel uses a similar signaling format, the base station 200 returns the uplink paging acknowledgment channel to the user (eg, the WT 300) when the base station 200 returns to an active state. Can be treated as a special access attempt. For example, base station 200 may determine timing correction from the uplink paging acknowledgment channel signal to initiate timing correction of the user (eg, WT 300) and to establish an appropriate radio link channel. You can assign resources to users.

In some embodiments (eg, where the first paging signal carries information allowing identification of a particular paged wireless terminal), an acknowledgment signal may be sent by the WT 300 in response to the first paging signal. have.

In another embodiment of the present invention, the slots assigned to each paging group are not constant and may vary based on a predetermined interest between base station 200 and WT 300. For example, consider the eight paging groups A, B, C, D, E, F, G, H of FIG. 7 and assume that no extension bits are used. During one example paging interval 744, the base station 200 attempts to page two WTs (eg, WTE1, WTG1). BS 200 transmits a first paging signal 706 that includes information bits = 00001010. The wireless terminals of group E and group G recognize that they have potential pages and that both groups have pages. In this embodiment, the second paging signal may advance to the slot position in view of unused slots. The paging signal for WTE1 is sent to the first second paging slot (e.g., the slot normally reserved for the second (group A) paging signal 710), and the paging signal for WTG1 is the second second paging. A slot (eg, a slot normally reserved for a second (group B) paging signal 712).

10 modulates five first paging information bits (eg, first paging information bits 266) of a first information message (eg, first paging signal message 252) into a first information signal. One exemplary method of an asynchronous modulation scheme that can be used to represent is shown. In the figure, 1000 represents 32 tones (tone 0 1021, tone 1 1022, tone 2 (1023), tone 3 (1024), tone 4 (1025), tone 5 (1026), tone 6 (1027), Tone 7 (1028), Tone 8 (1029), Tone 9 (1030), Tone 10 (1031), Tone 11 (1032), Tone 12 (1033), Tone 13 (1034), Tone 14 (1035), Tone 15 (1036), tone 16 (1037), tone 17 (1038), tone 18 (1039), tone 19 (1040), tone 20 (1041), tone 21 (1042), tone 22 (1043), tone 23 (1044) ), Tone 24 (1045), tone 25 (1046), tone 26 (1047), tone 27 (1048), tone 28 (1049), tone 29 (1050), tone 30 (1051), tone 31 (1052)) Downlink frequency axis 1002 divided by. The method shown in FIG. 10 is on / off keying. For transmission of the first paging message signal at any given time (eg, exemplary OFDM symbol time 1040), one tone of the 32 tone sets is transmitted at the applied power and the other 31 tones are Does not send anything. Four examples of the first paging message signal are shown in FIG. In the exemplary first paging signal 1001, power is applied to tone 0 1021 (as indicated by 1 at position 1062) and not to the other 31 tones of the tone set. In the exemplary first paging signal 1003, power is applied to tone 1 1022 (as indicated by 1 at position 1064) and not to the other 31 tones of the tone set. In the exemplary first paging signal 1005, power is applied to tone 2 1023 (as indicated by 1 at position 1066) and not to the other 31 tones of the tone set. In the exemplary first paging signal 1007, power is applied to tone 3 1024 (as indicated by 1 at position 1068) and not to the other 31 tones of the tone set. The WT 300 receiving the first paging signal does not need to set a channel estimate. WT 300 wakes up at the appropriate time to receive the first paging message signal for one OFDM symbol period, performs FFT, sets one tone (frequency) of much higher power, and calculates five information bits can do.

The on / off asynchronous modulation method described with respect to FIG. 5, illustrated with exemplary five information bits and thirty-two tones, provides a different number of first information bits and different number of tones (e.g., k information bits, two). ^k tones).

In another embodiment, five information bits may be conveyed by associating the on / off state of the 32 tones with 32 code words. In general, the k first information bits of the first paging signal may be delivered in 2 ^k orthogonal units.

11 is an asynchronous that may be used to modulate five first information bits (eg, first paging information bits 266) of an information message (eg, a first paging signal message) into a first information signal. Another exemplary method of modulation is shown. In the figure, 1100 represents 32 tones (Tone 0 1121, Tone 1 1122, Tone 2 (1123), Tone 3 (1124), Tone 4 (1125), Tone 5 (1126), Tone 6 (1127), Tone 7 (1128), Tone 8 (1129), Tone 9 (1130), Tone 10 (1131), Tone 11 (1132), Tone 12 (1133), Tone 13 (1134), Tone 14 (1135), Tone 15 (1136), tone 16 (1137), tone 17 (1138), tone 18 (1139), tone 19 (1140), tone 20 (1141), tone 21 (1142), tone 22 (1143), tone 23 (1144) ), Tone 24 (1145), tone 25 (1146), tone 26 (1147), tone 27 (1148), tone 28 (1149), tone 29 (1150), tone 30 (1151), tone 31 (1152)) Downlink frequency axis 1102 divided by. Thirty-two tones have seven tone subsets: tone subset 0 1116 (tones 0-4), tone subset 1 1162 (tones 4-7), tone subset 2 1163 (tones 8-11), tone subsets 3 (1164) (Tone 12-15), Tone Subset 4 (1165) (Tone 16-19), Tone Subset 5 (1166) (Tone 20-23), Tone Subset 6 (Tone 24-27), Tone Subset 7 (Tons 28--31).

In a given first paging message signal, a specific one tone subset is transmitted but the tones of the other seven tone subsets are not transmitted. This selection of the eight tone subsets carries information bits (eg, three first paging information bits). Each tone subset of FIG. 11 is arranged such that the tones of the tone subset are physically continuous tones. So assuming that the radio channel response does not vary too much between physically consecutive tones, additional information (e.g., two first paging information bits) can be transmitted by modulating the information of the tones of any one tone subset. . For example, a differential modulation scheme or an orthogonal modulation scheme may be used for successive tones of any tone subset. 11 assumes that a quadrature phase modulation scheme is used for the selected tone subset. The quadrature phase modulation scheme of FIG. 11 allows for four consecutive phases of the selected (power transmission) tone subset: ++++, ++-, +-+-, +-+ , + Represents 0 degree phase and-represents 180 degree phase. Four examples of the first paging message are shown in FIG. In the exemplary first paging signal 1101, transmit power is applied to four tones of the first tone subset 0 1161 and not to the other 28 tones of the other seven tone subsets, the phase of which corresponds to the corresponding box ( As indicated by 1171, 1172, 1173, and 1174, four tones 1121, 1122, 1123, and 1124 are set to ++++, respectively. In the exemplary first paging signal 1103, transmit power is applied to four tones of the first tone subset 0 1161 and not to the other 28 tones of the other seven tone subsets, the phase being corresponding to the box ( As shown in 1175, 1176, 1177, and 1178, the four tones 1121, 1122, 1123, and 1124 are set to ++-, respectively. In the exemplary first paging signal 1105, transmit power is applied to four tones of the first tone subset 0 1161 and not to the other 28 tones of the other seven tone subsets, the phase being corresponding to the box ( As shown by 1179, 1180, 1181, and 1182, four tones 1121, 1122, 1123, and 1124 are set to +-+-, respectively. In the exemplary first paging signal 1107, transmit power is applied to first tone subset 0 1161 and not to the other 28 tones of the other seven tone subsets, with the phases corresponding to boxes 1183, 1184, As shown in 1185 and 1186, four tones 1121, 1122, 1123, and 1124 are set to +-+, respectively. The WT 300 receiving the first paging signal does not need to set channel estimates, need to have channel estimate information, or rely on channel state history. The WT 300 wakes up at an appropriate time to receive the first paging message signal during one OFDM symbol period (e.g., time interval 1104), performs an FFT, and executes (the three first paging message information bits). It is possible to determine a tone subset of much higher power than other tone subsets to obtain, and make the best decision of which of the four code words has been transmitted (acquiring two additional first paging information bits).

12 is a flow chart 1200 illustrating an exemplary method of operating a base station to page a wireless terminal (WT) in a communication system including a plurality of wireless terminals in accordance with the present invention. Exemplary base station paging methods begin at base station phase 1202 where at least one base station is initialized, starting with a predetermined timing sequence in connection with the transmission of a paging signal, for example, and receiving and / or receiving a paging message to be transmitted. Or begin to generate. Operation proceeds from step 1202 to step 1204.

In step 1204, the base station determines whether there is a paging message to send for the first group of WTs. For example, a paging message can be queued for transmission. This paging message may be generated in response to the peer node of the WT to be paged attempting to establish a communication session with the WT to be paged. The base station on which the page is queued may be the last known attachment point of the WT to be paged. If there is a paging message to be sent to the first group of WTs, the operation proceeds to step 1206; otherwise, the operation proceeds to step 1208.

In step 1206, the base station modulates a first number of information bits, e.g., one bit of information, in a first modulation type, e.g., asynchronous modulation, to convey the first number of information bits. Operative to generate a paging signal, the first paging signal including information indicating that there is a paging message to be transmitted for at least one of the first group of wireless terminals. Some types of asynchronous modulation schemes that can be used in various embodiments include on / off modulation, quadrature modulation, and differential modulation. Operation proceeds from step 1206 to step 1210.

In step 1208, the base station modulates a first number of information bits, e.g., one bit of information, in a first modulation type, e.g., asynchronous modulation, to convey the first number of information bits. Operative to generate a signal, the first paging signal including information indicating that there is no paging message to be transmitted. Some types of asynchronous modulation schemes that can be used in various embodiments include on / off modulation, quadrature modulation, and differential modulation. Operation proceeds from step 1208 to step 1210.

Next, at step 1210 the base station operates to transmit the first paging signal to a communication coverage area, for example a cell or sector. In some OFDM embodiments, the first paging symbol is transmitted in a time period whose duration is shorter than 4 symbol times, for example 1, 2 or 3 symbol times, the symbol time corresponding to the time period used for symbol transmission. . During symbol time, for example, multiple symbols may be transmitted simultaneously using different tones. Transmission of the first paging signal may include sending the first paging signal to a communication channel. As mentioned above, the first modulation method is a modulation method, for example, an asynchronous modulation method, in which communication channel information does not need to be used by the WT to demodulate the modulated information.

Operation proceeds from step 1210 to step 1212. In step 1212, a check is made as to whether step 1204 indicates that the paging message will be sent. If it is determined in step 1204 that the paging message is to be sent, operation proceeds to step 1214, otherwise there is no paging message to be sent and the operation returns to step 1204.

In step 1214, the base station operates to modulate a second number of information bits with a second modulation type different from the first modulation type to generate a second paging signal, wherein the second paging signal is a paging signal. Include at least a portion of the paging message when indicating that there is a message. In many embodiments, the second information bit number is different from the first information bit number, and the second information bit number is greater than the first information bit number. Some types of synchronous modulation schemes that may be used in various embodiments include quadrature phase shift keying and quadrature amplitude modulation. In some embodiments, the second paging signal may include information used to identify the WT in the system. In some embodiments, the second paging signal includes information that can uniquely identify the WT within the WT group. In some embodiments where the first paging signal indicates a group of communication devices, the second paging signal indicates to which particular paging device in the group a paging message is delivered.

Operation proceeds from step 1214 to step 1216 where the base station is operative to send a second paging signal, for example to a communication coverage area, for example a cell or sector. In many embodiments, the second modulation type, for example the synchronous modulation method, requires the use of communication channel information by the WT to demodulate information modulated with the second modulation type. In various embodiments in which the first and second paging signals are transmitted at different times, the second paging information signal is transmitted at a first predetermined time offset from the transmission time of the first paging information signal. In various OFDM embodiments, the second paging signal is transmitted at least two symbol times after completion of the transmission of the first paging signal.

Operation proceeds from step 1216 to step 1204 again, where the BS checks again whether there is a paging message to be sent to the WT of the first group.

In some embodiments, there are multiple WT paging groups, and some of the WT groups are multicast groups that include multiple WTs. Confirmation of step 1204 may be extended to each paging group. The first paging signal may indicate that there is no paging message for any WT in the first WT group, but there is a paging message for at least one WT in the second WT group. In some embodiments, the first paging signal may indicate which of the paging groups has a member to receive the paging message, for example, a plurality of paging groups corresponding to each second paging group having a member to receive the page. There may be a second paging signal.

In various embodiments in which the first paging signal indicates a group of communication devices, multiple second paging signals may be generated that correspond to different WTs in the group to which each message is directed. In such an embodiment, the second paging message may be sent at different time periods with the offset according to the group member to which the message to be sent for the second paging signal corresponds.

13 is a flow chart 1300 illustrating an exemplary method of operating a wireless terminal to receive and process a paging signal in accordance with the present invention. Operation begins in step 1302, where the exemplary WT is in a sleep mode operating state. The sleep mode, which is at a lower WT power consumption than the active mode, allows the WT to hold some timing information to determine whether it is occasionally woken up or paged periodically. Operation proceeds to step 1304 where the WT wakes up in a sleep mode operation to operate to receive the first paging signal. Internal retention timing information used to maintain timing synchronization with the BS and time tracking in the WT allow to determine when the WT should wake up and to anticipate transmission of the first type paging signal from the BS.

Next, at step 1306 the WT operates to receive the first paging signal. In some OFDM embodiments, the first paging signal has a duration of less than 4 symbol times. In some OFDM embodiments, the first paging signal is one or two OFDM symbols. Next, at step 1308, the WT operates to perform an asynchronous demodulation operation on the received first paging signal that generates demodulated information. This asynchronous demodulation operation does not require channel estimation information and is not normally used. Operation proceeds from step 1308 to step 1310. In step 1310, the WT operates to determine whether the demodulated information indicates that a paging message is being sent following the first paging signal. Next, operation proceeds to step 1316 if a paging message is being sent in step 1312, and operation proceeds to step 1314 if a paging message is not being sent.

At step 1316, the WT operates to return to sleep mode, and operation returns to step 1304 by connection node A 1332 to wake up the WT again at an appropriate time for the next first paging signal.

In step 1314, the WT operates to return to sleep mode operation, for example. Operation proceeds from step 1314 to step 1318 where the wireless terminal wakes up from the sleep mode operation for another time before receiving the second paging signal. The WT wakes up well ahead of the expected second paging signal in consideration of the completion of the channel estimation. In a next step 1320, the WT is initialized to operate to perform a channel estimation operation. The channel estimation operation may include, for example, receiving pilot symbols, performing FFT on received pilot symbols, for example, 10-20 pilot symbols, and determining channel estimates from processed information. Next, at step 1322, the WT operates to receive a second paging signal, eg, a paging signal comprising at least 10 symbols.

Next, in step 1324, the WT performs a synchronous demodulation operation on the second paging signal using the channel estimation information acquired in step 1320. The second paging signal includes a second number of information bits, while the first paging signal includes a first number of paging bits. The first and second numbers of information bits may be the same. However, in many embodiments, the second paging bit number is greater than the first paging bit number. In some embodiments, the demodulated second paging information includes a portion of the WT identifier and / or a portion of the paging message. In some embodiments, the WT is all or part of a paging message. In some embodiments, the paging message includes additional information other than mobile node information, commands or simple mobile node identification information.

At step 1326, a determination is made whether the page was intended for the WT based on the decoded information of the second paging message alone or in combination with information from the decoded first paging message. For example, the first paging signal can identify the WT group and the second paging signal can identify the specific or unique WT to which the paging message is delivered. In some embodiments, the information obtained from the demodulation of the second paging signal includes a portion of the WT identifier, and operation of step 1326 includes determining whether a page is delivered to the WT from at least a portion of the WT identifier. . In some embodiments, the portion of the WT identifier provided in the second paging message in combination with the group identifier of the first paging message information uniquely identifies the WT to which the paging message is sent in the communication system.

If it is determined in step 1326 that the page is not delivered to the WT, operation proceeds to step 1330, where the WT is operative to return to sleep mode operation. However, if at step 1326 determines that the WT is the intended recipient of the page message, the operation proceeds to step 1328 where the WT responds to the page. Such a response may include, for example, confirming that a page has been received, establishing and participating in a communication session with a peer node, and eventually transitioning to sleep mode.

From step 1330 or step 1328, the operation returns to step 1304 by connection node A 1332 and the WT wakes up for another first paging message at an appropriate time.

In some embodiments, the system supports the maximum number of WTs that can be registered to simultaneously receive pages in the system, and the first number of information bits carried in the first paging signal uniquely identifies each of the maximum number of WTs. Less than the number of bits needed to In such an embodiment, the information included in the first paging message in combination with the information of the second paging message may uniquely identify the WT in the system.

Although primarily described in relation to OFDM systems, the method and apparatus of the present invention may be applied to a wide range of communication systems including many non-OFDM and / or non-cellular systems.

In various embodiments, a node described herein may include one or more modules, such as a paging module modulation module, a paging signal detection module, a demodulation module, a communication module, a timing module, etc., for performing steps corresponding to one or more methods of the present invention. Implemented using In some embodiments, various aspects of the invention are implemented using modules. Such modules may be implemented using software, hardware or a combination of software and hardware. Many of the methods or method steps described above are machine readable, such as a memory device for controlling a machine, for example a general purpose computer with or without additional hardware, to implement all or part of the methods described above, for example, on one or more nodes. It may be implemented using machine executable instructions, such as software contained in a possible medium, for example, RAM, floppy disk, and the like. Accordingly, the present invention relates, among other things, to machine readable media comprising machine executable instructions for causing a machine, such as a processor and associated hardware, to perform one or more steps of the method (s) described above.

Various further modifications to the methods and apparatus of the present invention described above will be apparent to those skilled in the art in view of the above description of the present invention. Such modifications should be considered to be within the scope of the present invention. The method and apparatus of the present invention may be applied to CDMA, orthogonal frequency division multiplexing (OFDM), and / or other types of communication techniques that may be used to provide a wireless communication link between an access node and a mobile node, and in various embodiments Is being applied. In some embodiments, the access node is implemented as a base station that establishes a communication link with the mobile node using OFDM and / or CDMA. In various embodiments, the mobile node is implemented as a notebook computer, a personal data terminal (PDA), or other portable device including receiver / transmitter circuitry and logic and / or routines for implementing the method of the present invention.

Claims (51)

A method of paging a wireless terminal, Modulating information of a first number of bits to generate a first paging signal indicating whether a paging message is present for at least one wireless terminal in the first group of wireless terminals, the first group being multiple One of the group of wireless terminals of the group and comprising a plurality of wireless terminals; Modulating a second number of bits of information to generate a second paging signal, wherein the second paging signal is information for identifying an individual wireless terminal in the first group to which the paging message is assigned when a paging message is present; And in communication with at least a portion of the information and the paging message; Transmitting the first paging signal; And And transmitting the second paging signal. The method of claim 1, Modulating the information of the first number of bits includes modulating information of a plurality of individual bits, some of the individual bits corresponding to different groups of wireless terminals, the group of wireless terminals And the respective bits corresponding to indicate whether or not a paging message exists for at least one wireless terminal in the group of corresponding wireless terminals. The method of claim 2, The second paging signal is a second type paging signal, the method, Generating another second type paging signal corresponding to the first signal, the another second type paging signal communicating at least a portion of a second paging message, wherein the second paging message is the first wireless terminal; For a wireless terminal in a second group of wireless terminals different from the group; And And transmitting the another second type paging signal. The method of claim 3, wherein Transmitting the second paging signal is performed at a first fixed time offset from a time at which the first paging signal is transmitted, Transmitting the second type of paging signal is performed at a second fixed time offset from a time at which the first paging signal is transmitted. The method of claim 1, Transmitting the second paging signal includes transmitting the second paging signal in one of a plurality of different paging signal time slots corresponding to the first paging signal, wherein the second paging signal is transmitted. Wherein the time slot is determined based on which wireless terminal the second paging message is assigned to in the first group of wireless terminals. The method of claim 5, wherein Modulating the information of the first number of bits is performed using a first modulation type, Modulating the information of the second number of bits is performed using a second modulation type different from the first modulation type, the second modulation type to demodulate information modulated with the second modulation type. Wireless terminal paging method, characterized in that it requires the use of communication channel information. delete delete delete delete The method of claim 6, The first modulation type is one of orthogonal modulation and differential modulation, And wherein said second modulation type is one of quadrature phase shift keying and quadrature amplitude modulation. delete delete delete delete delete delete The method of claim 1, And the information included in the first paging signal, in combination with information for identifying individual wireless terminals included in the second paging signal, uniquely identifies a wireless terminal in the system. delete delete A base station communicating with wireless terminals, First paging signal generating means for periodically generating paging signals of a first type, the paging signals of the first type indicating whether a paging message is to be transmitted to at least one wireless terminal in a first group of wireless terminals, and The first group is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals; Second paging signal generating means for generating a paging signal of a second type, the paging signal of the second type comprising information for identifying an individual wireless terminal in the first group to which the paging message is assigned; A paging signal communicates with the information and at least a portion of the paging message; And Means for transmitting the first and second type paging signals. The method of claim 21, The means for generating the first paging signal comprises means for modulating a plurality of individual bits of information, some of the individual bits corresponding to different groups of wireless terminals, the individual corresponding to the group of wireless terminals. And a bit indicates whether a paging message exists for at least one wireless terminal in the group of corresponding wireless terminals. The method of claim 21, Control transmission of the second type paging signal at a first fixed time offset from the time at which the first type paging signal is transmitted, and another at a second fixed time offset from the time at which the first type paging signal is transmitted. And transmission timing means for controlling the transmission of the second type paging signal. The method of claim 21, Signaling means for controlling the transmitting means to transmit the second type paging signal in one of a plurality of different paging signal time slots corresponding to the first type paging signal, And the specific time slot in which the second type paging signal is transmitted is determined based on which wireless terminal within the first group of wireless terminals is assigned. As an operation method of a wireless terminal, Awake in a sleep mode operation to receive a first paging signal indicating whether a paging message is present for at least one wireless terminal in a first group of wireless terminals, the first group being multiple Is one of a group of wireless terminals and includes a plurality of wireless terminals, the wireless terminal being a member of the first group; Performing a first demodulation operation on the first paging signal to produce demodulated information; Determining whether the demodulated information indicates that a paging message has been sent to at least one member of the first group; And If the demodulated information is determined to indicate that the paging message has been sent to at least one member of the first group, i) performing a second demodulation operation on the second paging signal, and ii) determining from the information included in the second paging signal whether the second paging signal includes at least a portion of a paging message directed to the wireless terminal. The method of claim 25, If it is determined that the demodulated information indicates that the paging message has not been sent, returning to a sleep mode operation. The method of claim 25, The demodulated information generated by demodulating the first paging signal includes information of a plurality of individual bits, some of the individual bits corresponding to different groups of wireless terminals, corresponding to the group of wireless terminals. The individual bits indicate whether a paging message exists for at least one wireless terminal in the group of wireless terminals to which the individual bits correspond; Determining whether the demodulated information indicates that a paging message has been sent to at least one member of the first group includes the plurality of individual bits corresponding to the first group of wireless terminals to effect the determination. Checking the bits in the field. The method of claim 27, Wherein the plurality of second paging signals corresponds to the first paging signal, the second paging signals have different time offsets from the first paging signal, and the method further comprises: Receiving the second paging signal at a time offset from the point in time at which the first paging signal is received, the time offset being a predetermined time offset corresponding to the first group of the wireless terminal; Wireless terminal operation method further comprising. The method of claim 28, Returning to the sleep mode operation before receiving the second paging signal; Waking from the sleep mode operation for another time prior to receiving the second paging signal; And Initiating a channel estimation operation prior to receiving the second paging signal; And the wireless terminal consumes less power in the sleep mode operation than when operating in the active mode operation that occurs when waking from the sleep mode operation. The method of claim 25, The first demodulation operation is an asynchronous demodulation operation without using channel information. And wherein said second demodulation operation is a synchronous demodulation operation using communication channel estimates to perform said demodulation operation. The method of claim 25, And wherein the first paging signal comprises a first number of bits and the second paging signal comprises a second number of bits greater than the first number of bits. delete delete delete As a wireless terminal, Means for performing a first demodulation operation on a first paging signal, wherein the first paging signal indicates whether a paging message exists for at least one wireless terminal in a first group of wireless terminals, and wherein the first group Is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals, wherein the wireless terminal is a member of the first group, and wherein the first demodulation transmits a designated paging message to at least one member of the first group. Restore the modulated information indicating whether to be present; When the information recovered from the first paging signal indicates that a paging message corresponding to the first paging signal will be transmitted, control the wireless terminal to receive a second paging signal of a second type at a preselected time; When information restored from the first paging signal indicates that a paging message corresponding to the first paging signal is not to be transmitted, enter the sleep mode operation to maintain the sleep mode operation until after the preselected time. Control means for controlling the terminal; And Perform a second demodulation operation on the received second paging signal to recover modulated information including at least a portion of a paging message directed to the wireless terminal and information for identifying an individual wireless terminal in the first group A wireless terminal comprising means. 36. The method of claim 35 wherein And means for performing a channel estimation operation after receipt of the first paging signal and before reception of the second paging signal including information indicating that a paging message will be transmitted. The method of claim 36, Timing control for controlling the wireless terminal to enter a sleep mode operation after receiving a first paging signal including information indicating that a paging message will be transmitted and to wake the wireless terminal to a more active state before the preselected time And a means further comprising a means. delete 36. The method of claim 35 wherein Means for performing a first demodulation operation on the first paging signal to recover modulation information indicating whether a paging message corresponding to the first paging signal is to be transmitted includes an on / off modulation demodulator, an orthogonal modulation demodulator and a differential modulation. A wireless terminal comprising at least one of the demodulators. 36. The method of claim 35 wherein Means for performing a second demodulation operation on the second paging signal comprises at least one of a quadrature phase shift keying modulation demodulator and a quadrature amplitude modulation demodulator. A base station for communicating with wireless terminals, A first paging signal generation module for periodically generating a first type of paging signals, the paging signals of the first type indicating whether a paging message will be sent to at least one wireless terminal in the first group of wireless terminals, and The first group is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals; A second paging signal generation module for generating a second type of paging signal, wherein the second type of paging signal includes information for identifying an individual wireless terminal in the first group to which the paging message is assigned; A paging signal is in communication with the information and at least a portion of the paging message; And And a transmitter for transmitting the first and second types of paging signals. 42. The method of claim 41 wherein The first paging signal generation module includes a modulation module for modulating a plurality of individual bits of information, some of the individual bits corresponding to different groups of wireless terminals, each corresponding to a group of wireless terminals. And a bit indicates whether a paging message exists for at least one wireless terminal in the group of corresponding wireless terminals. 42. The method of claim 41 wherein Control transmission of the second paging signal at a first fixed time offset from the time at which the first paging signal is transmitted, and another second paging at a second fixed time offset from the time at which the first paging signal is transmitted The base station further comprises a transmission timing module for controlling the transmission of the signal. 42. The method of claim 41 wherein A signaling module for controlling the transmitter to transmit the second paging signal in one of a plurality of different paging signal time slots corresponding to the first paging signal, And the specific time slot in which the second paging signal is transmitted is determined based on which wireless terminal within the first group of wireless terminals is assigned. A computer readable medium containing machine executable instructions for use in a base station communicating with wireless terminals, the method comprising: Instructions for causing the base station to modulate information of the first number of bits to generate a first paging signal indicating whether a paging message exists for at least one wireless terminal in the first group of wireless terminals; The first group is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals; Instructions for causing the base station to modulate a second number of bits of information to generate a second paging signal, wherein the second paging signal is a separate radio in the first group to which the paging message is directed when a paging message is present; Information for identifying a terminal, and in communication with at least a portion of said information and said paging message; Instructions for causing the base station to transmit the first paging signal; And And instructions for causing the base station to transmit the second paging signal. The method of claim 45, The instruction for causing the base station to modulate information of the first number of bits includes modulating a plurality of individual bits of information, some of the individual bits corresponding to different groups of wireless terminals, wherein the wireless The individual bits corresponding to the group of terminals, wherein the individual bits indicate whether a paging message is present for at least one wireless terminal in the group of corresponding wireless terminals. As a wireless terminal, A first demodulation module for performing a first demodulation operation on a first paging signal, wherein the first paging signal indicates whether a paging message exists for at least one wireless terminal in a first group of wireless terminals, The first group is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals, wherein the wireless terminal is a member of the first group and the first demodulation is assigned to at least one member of the first group. Perform modulated information to indicate whether a paging message is to be sent; When the information recovered from the first paging signal indicates that a paging message corresponding to the first paging signal is to be transmitted, control the wireless terminal to receive a second paging signal of a second type at a preselected time; The wireless terminal to enter a sleep mode operation to maintain the sleep mode operation until after the preselected time when the information recovered from the first paging signal indicates that a paging message corresponding to the first paging signal will not be transmitted; A control module for controlling the; And Performing a second demodulation operation on the received second paging signal to recover modulated information comprising at least a portion of a paging message directed to the wireless terminal and information for identifying an individual wireless terminal in the first group A wireless terminal comprising a second demodulation module for. The method of claim 47, And a channel estimation module for performing a channel estimation operation after reception of the first paging signal and before reception of the second paging signal including information indicating that a paging message will be transmitted. The method of claim 48, Timing the wireless terminal to control the wireless terminal to enter a sleep mode operation after receipt of a first paging signal comprising information indicating that a paging message will be transmitted, and to wake the wireless terminal to an active state prior to the preselected time The wireless terminal further comprises a control module. A computer readable medium containing machine executable instructions for use in a wireless terminal, the method comprising: Instructions for causing the wireless terminal to wake up in sleep mode operation to receive a first paging signal indicating whether a paging message is present for at least one wireless terminal in the first group of wireless terminals-the first The group is one of a plurality of wireless terminal groups and includes a plurality of wireless terminals, the wireless terminal being a member of the first group; Instructions for causing the wireless terminal to perform a first demodulation operation on the first paging signal to produce demodulated information; Instructions for causing the wireless terminal to determine whether the demodulated information indicates that a paging message has been sent to at least one member of the first group; And The wireless terminal, i) if the demodulated information is determined to indicate that a paging message has been sent to at least one member of the first group, perform a second demodulation operation on a second paging signal, ii) instructions for determining from the information included in the second paging signal whether the second paging signal includes at least a portion of a paging message directed to the wireless terminal. 51. The method of claim 50, And if the demodulated information is determined to indicate that the paging message was not sent, causing the wireless terminal to return to sleep mode operation.

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