JP2002077990A - Update of overhead message by distributed control - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system and a method, which give a simple but effective technology for communication an overhead message in a wireless communication system supplying access to a distributed network while band width is saved and power consumption is set to be minimum. SOLUTION: A wireless base station connected to the distributed network transmits a series of signatures in the overhead message to a mobile unit. The mobile unit wakes up and receives the signatures and compares them with a signatures stored in the mobile unit. When the signatures received by the mobile unit differ from the signatures stored in the mobile unit, the mobile unit receives the overhead message transmitted by the wireless base station while it is kept wake up. When the signatures received by the mobile unit are the same as those stored in the mobile unit, the mobile unit returns to sleep.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates generally to wireless communication systems, and more particularly, to the distribution of overhead channel information in wireless communication systems.

[0002]

BACKGROUND OF THE INVENTION In a cellular communication system, the area to be covered is divided into many smaller areas called cells, and one base station (BS) is provided to provide service or coverage to mobile units within the cell. Is arranged. Each BS is connected to a base station controller (BSC),
The base station controller is used to control some BSs and to provide communication services to mobile units as the mobile unit moves from one cell to another. The BSC is then connected to a Mobile Switching Center (MSC), which is typically a telephone switch with special software that handles the mobility aspects of mobile units. Most cellular communication systems have multiple M
Consisting of SCs, each MSC has its own MS and is interconnected by fixed links. The MSC interconnects with the Public Switched Telephone Network (PSTN) for both outgoing calls to and incoming calls from the fixed telephone.

A mobile unit transmits radio frequency (R) signals to a BS.
F) Radio reverse (mobile unit to BS) link and RF forward from BS (BS to mobile unit)
It is finally connected to the MSC through a link. RF
Signals are exchanged between a particular mobile unit and one or more base stations over these links. Mobile units do not communicate directly with each other. Communication from mobile unit to mobile unit over a span of one or more cells occurs through a base station serving the mobile unit that wants to communicate. Base stations communicate with the BSC using various media, such as a terrestrial-based wired or microwave link. The BSC can route calls to the PSTN through the MSC and can route packets to packet switched networks such as the Internet. The base station controller also coordinates the operation of base stations in the system, for example, during handoff.

[0004] A common feature of the RF forward and reverse links of many cellular systems is the multiple users using a single communication channel that occupies a limited frequency range. Cellular systems utilize various techniques that allow multiple users to use a single communication channel that occupies a limited frequency range. Code division multiple access (CDMA) is one such technique. CDMA
A popular standard for is "mobile stations for dual mode wideband spread spectrum cellular systems-
Base station compatibility standard "can be found in the TIA / EIA standard TIA / EIA-95-B. C
With DMA, multiple users can simultaneously use the entire communication channel without having to adjust the timing of transmission and some of the communication channels used by each user.
A more detailed description of CDMA and spread spectrum communications can be found in Addison-Wesley Publishing Company, Reader, M.D. A.
In 1996, Andrew J. et al. Viterbi spectrum
It can be found in the CDMA principle of spread communication . CDM
In contrast to A, the other two multiple access techniques adjust the timing of user transmissions (Time Division Multiple Access (TDM)
A)) or adjust a part of the communication channel used by the user (frequency division multiple access (FDMA)).

[0005] Regardless of the technology used to provide multiple access in a typical cellular system, a forward communication link includes one or more data channels, a pilot channel, and one or more paging channels. And these are all transmitted from the base station to the mobile unit. The pilot channel or pilot signal functions to define the boundaries of the cell area served by the base station. In a CDMA cellular system according to IS-95, the pilot signal functions for other purposes as well. For example, the pilot signal provides a time reference, provides amplitude and phase tracking, and allows the mobile unit to identify and synchronize with various base stations within its communication capabilities. A set of data channels carries data related to various communication sessions (typically telephone calls) and is directed to individual mobile units. These data channels are often called traffic channels. The paging channel is used by the base station to notify the mobile unit when a communication request has been received. The paging channel is also used to send overhead messages. The overhead message contains information enabling communication from the mobile unit to the base station.

[0006] The overhead messages are not addressed to any particular mobile unit, but are intended to be distributed to each mobile unit within the corresponding coverage area. In an IS-95 CDMA cellular system, there are four types of overhead messages: system parameters, access parameters, channel list overhead messages, and neighbor list overhead messages. Each type of overhead message must be broadcast at least once every second. For example, the neighbor list overhead message continuously broadcasts a list of neighbor base stations with which communication is possible. When the mobile unit enters the coverage area of a neighbor base station, it uses this neighbor list to monitor signals from neighbor base stations. Cellular systems that use other communication standards may use other types of overhead messages.

[0007] Overhead messages are generally received and processed by the mobile unit when the mobile unit is not busy or is not attempting to connect the call (ie, when the mobile unit is "idle"). Is done. The term idle is somewhat misleading because mobile stations can be very busy during idle.

[0008] During the idle state, the mobile station wakes up periodically, listens to a paging channel and processes messages on that channel. Over time, the mobile station may wake up periodically and listen to the paging channel, and the overhead message may remain the same. Waking up the mobile station only to determine that the overhead message is the same as the previously decoded previous message in terms of saving and using battery power,
Since it is not preferable to have the overhead message received and decoded, the sequence number is transmitted together with the overhead message. When the mobile station wakes up, it receives the sequence number of the overhead message and determines whether to receive the overhead message while the mobile station is waked up.
In many examples, the mobile unit goes back to sleep after receiving the sequence number. The reason is that the received sequence number has the same sequence number as the sequence number received when the mobile unit last wakes up.

The mobile unit performs the listening function because listening for overhead messages requires a certain amount of power and the listening function is performed frequently (such as once every second). Limiting the amount of time spent reduces the overall power consumption of the mobile unit, and thus increases the life of any battery or other power storage system utilized by the mobile unit. In many cases, significant power savings result because the overhead messages remain the same for a significant period of time.

[0010] In many cellular systems, overhead messages and sequence numbers transmitted by base stations are controlled from a central location such as a BSM. One reason for providing this centralized control generally stems from the nature of the services provided by cellular systems. Cellular systems typically provide voice services or connections to terrestrial-based PSTNs. PSTN generally has a highly centralized switching structure. As a result, cellular services that want to interface to the PSTN must use a central switch to route calls. In many cellular systems that provide voice services over the PSTN, telephone calls are bundled at a central switch (MSC) for transmission over the PSTN and unbundled for transmission over a wireless network.
As a result, since there is a central location (BSM or MSC) where links from many BSs terminate, this central location is used to centralize the overhead message and sequence number programming at each base station in the cellular system. Remote control from the location was inevitable.

[0011] In contrast, cellular systems that provide packet data services rather than voice services generally interface with highly distributed networks. An example of a decentralized network is the Internet. Cellular systems that provide packet data services provide a wireless link from a cellular system user to a router, which links the user to a decentralized network. Technically, the Internet is Transmission Control Protocol / Internet Protocol (TCP / IP)
A set of standard protocols, such as, that allow dissimilar computer systems and networks to send and receive information. Among the more popular protocols are e
E-mail (electronic message transmission), file transfer protocol (file transfer processing), World Wide Web (link using graphic interface using hypertext document), telnet (telephone network connection), IRC (internet relay chat), gopher (information organization) It is included.

[0012] Messages received from mobile users of the packet data cellular system are forwarded to the router by the base station. Routers break down messages into smaller pieces known as packets. The packets travel separately across the network, but are eventually reformed together when all pieces of the message arrive at their destination. During transmission, packets flow from one router to another, passing through bridges and switches. A specific route is not selected from the beginning.
Each router or switch looks at the destination address of the packet, but does not examine its contents, but determines the best route to send it.

Since a router typically connects directly to a decentralized network and typically sends data along multiple paths to a destination, a centrally located switch sets up a single path to and from the destination. Often there is no need to do so. As a result, in wireless data systems that provide access to a decentralized network, BSMs and MSCs that can also be used to control base stations and update overhead messages in cellular systems
There may not be a central location like.

[0014]

Accordingly, there is a need for delivery of overhead messages in a wireless communication system, such as a cellular system, that provides access to a decentralized network. The present invention fulfills this need.

[0015]

SUMMARY OF THE INVENTION The system and method of the present invention is simple to communicate overhead messages in a wireless communication system that provides access to a distributed network while saving bandwidth and minimizing power consumption. Provide effective technology.

In one embodiment, a wireless base station connected to a distributed network sends a series of signatures of overhead messages to a mobile unit. The mobile unit wakes up to receive the signatures and compares them with the signatures stored on the mobile unit. If the signature received by the mobile unit is different from the signature stored on the mobile unit, the mobile unit receives the overhead message transmitted by the wireless base station waking. If the signature received by the mobile unit is the same as the signature stored on the mobile unit, the mobile unit goes back to sleep.

In another embodiment, the mobile unit wakes up to receive a message from the wireless base station. The mobile unit uses the message to generate the signature. The mobile unit compares this signature with the signature of the previous message received by the mobile unit. If the signature generated for the received message is the same as the signature of the previously received message, the mobile unit goes back to sleep. If the signature generated for the received message is different from the signature of the previously received message, the mobile unit updates the operating parameters for use in communicating with the base station.

[0018]

FIG. 1 shows a system block diagram of a wireless communication system (CS or system) 200 according to a presently preferred embodiment of the present invention. The system 200 includes a plurality of base stations (BS) 210,
220 (only two are shown) and each base station 21 when the mobile unit (MU) 202 is within the geographic area covered by the base station.
0, 220 can communicate wirelessly with the mobile unit 202. The MU 202 has a terminal device (TE) 20
6 and a mobile terminal (MT) 204.

An MU is used to refer to a composite entity consisting of a terminal and a mobile terminal. In this description, the term "mobile unit" is used to generally refer to a remote subscriber station for the purpose of this description. However, it should be noted that the mobile unit may be fixed in a certain position. The mobile unit may be part of a subscriber system where multiple users are gathered. Mobile units may be used to carry a combination of voice, data or signal types. The term "mobile unit"
Is a technical term and is not meant to limit the scope or function of a unit.

Base stations 210 and 220 include base station transceiver subsystems (BTS) 212 and 222 and a radio link protocol and signaling manager (RS).
M) 214, 224 are included. A base station is used to refer to a composite entity consisting of BTS and RSM.

[0021] TE 206 is a device that provides a user interface, typically a laptop or notebook computer, or a personal digital assistant (PDA). TE206 is MT2
The MT 204 is a wireless device that provides data modulation / demodulation capability. The BTS 214 transmits M through a radio frequency (RF) radio interface.
Connected to T204. The BTS 214 provides data modulation / demodulation capability to connect with the MT 206. RSM21
4, 224 function as Radio Link Protocol (RLP) endpoints and signaling endpoints, mapping Internet Protocol addresses and mobile station identifiers to each other. There may be a single RSM or an RSM co-located with each BTS.

[0022] The system 200 also includes a router 230. The router 230 connects the RSMs 214, 224 to a distributed network 250 composed of routers (not shown) and other networks (not shown). One example of a distributed network is the Internet. System 200 may be connected to other types of distributed and / or centralized networks.

The RF radio interface between BTS 212 and MT 204 has a B for mobile unit communication.
A TS forward link and a mobile unit reverse link for BTS communication are included. In one embodiment, the forward link of system 200 is completely dedicated to a single mobile unit at any given moment, and a single forward channel is transmitted to one mobile unit at any given moment. There are many types of communication standards, and the present invention may be used with these communication standards. One standard for the forward and reverse links in wireless communication systems is the TIA / EIA standard TIA / EIA-95, entitled "Mobile-Base Station Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular Systems". -B (that is, IS-9)
It is specified in 5). In another embodiment, the system 2
The 00 forward link may be the same as the IS-95 forward channel. In IS-95, multiple forward channels are received by one mobile unit.

The forward link of system 200 is IS
−95, in which case IS-9
The pilot channel is transmitted in bursts, as opposed to the pilot channel being transmitted continuously as in FIG.
It may be embedded in the data channel. Other overhead channels may also be different, and the continuous synchronization and paging channels of IS-95 are combined into a single control channel in system 200, and the messages on this single control channel are "single user" forward. Time multiplexed on the link. Multiplexing is desirable because it avoids dividing the power of the base station into two or more continuously transmitted channels. Higher data rates can be used if substantially all base station power is used to transmit the data channel.

System 200 is designed to operate on a separate CDMA channel (ie, a different frequency) than the existing IS-95 system. System 20
0 can be deployed independently of the existing IS-95 system (or where no such system exists) and in such a case there is no interaction with the underlying voice system. The system 200 is a cooperative IS-9.
5 can be deployed to the location where the system exists,
In such a case, the relevant information of the IS-95 system is conveyed to the IS-95 system on the control channel of the system 200 supporting the handoff, and the information delivery from the IS-95 system to the system 200 is supported by the support of the call delivery notification. Is performed.

In system 200, an overhead channel, such as a paging channel, is time multiplexed with the forward data channel, and the less time spent transmitting the paging channel, the more available it is to transmit the forward data channel. Time increases.
For a given constant data rate, the data throughput for the mobile unit is the amount of time spent transmitting the paging channel since the forward data channel is directly related to the amount of time that is transmitted to and received by the mobile unit. Reducing the amount is highly desirable.

In TIA / EIA-95, the paging channel is transmitted continuously and takes part of the total available bandwidth on the forward channel and the total available power of the base station. The forward data channel can use less power because some of the total available power of the base station is taken by the paging channel. For a given signal-to-noise ratio (SNR) and a given bit error rate (BER), the maximum data transmission rate on the forward data channel is a function of the power available for the forward data channel. In particular, for a given SNR, as less power is available for the forward data channel, the maximum data transmission rate on the forward data channel must be reduced to satisfy the requirements for a given BER.

For many systems and applications, if a high data transmission rate is desired, then increasing the power at the base station transmitter may not allow more power to be available for the forward data channel. Absent. As a result, achieving a high transmission data rate requires taking power from the other channels and making that power available to the forward data channel.

Unfortunately, if too much power is taken from the paging channel and applied to the forward data channel, the SNR on the paging channel is adversely affected, and therefore the BER on the paging channel is also adversely affected. May obscure the information transmitted on the paging channel. However, if the transmitter power cannot be increased significantly to increase the data transmission rate, a significant amount of power may be taken from the paging channel (or some other channel) to reduce the available power for the forward data channel. It needs to be increased considerably.

To significantly increase the data transmission rate, it is necessary to take all the power from the paging channel, apply it to the forward data channel, and time multiplex the paging channel and the data channel. For a given transmitter power, a system where the paging channel and the data channel are time multiplexed,
A higher transmission data rate can be provided to the user than a system in which the paging channel and the data channel are transmitted simultaneously to share a given transmitter power.

Although it is true that a higher maximum transmission data rate is possible when the paging channel and the forward data channel are time multiplexed, in order to achieve a higher effective transmission data rate, the paging channel must be The time spent transmitting should be minimized as the following equation suggests.

Effective transmission data rate = Tr _Max * Tfd
/ (Tfd + Tpc) Tr _Max is the maximum transmission data rate, Tfd is the transmission duration of the forward data channel during one period, and Tpc is the transmission duration of the paging channel during one period.

FIG. 2 generally illustrates the structure of the forward link of an embodiment according to the present invention. The forward link is a data stream having a periodic cycle, and the data stream includes a forward data channel and a multiplexed paging channel. The paging channel includes a signature capsule and an overhead message capsule. In the embodiment shown in FIG. 2, the signature capsule and the overhead message capsule are transmitted during a period having a duration of 400 milliseconds. In other embodiments, this period may have other durations. The signature capsule contains at least one signature. The signature may represent only one overhead message, or may represent more than one group of messages (ie, if at least one message in more than one group of messages is changed, Signature changes at any time).

[0034] The overhead message capsule contains at least one overhead message.
The overhead messages are not addressed to any particular mobile unit, but are intended to be distributed to each mobile unit in the corresponding coverage area.

[0035] Possible overhead messages include system parameters, access parameters, channel list overhead messages and neighbor list overhead messages. Each type of overhead message must be broadcast at least once every second. In a preferred embodiment, the message is broadcast every 400 milliseconds. For example, the neighbor list overhead message can continuously broadcast a list of neighbor base stations and communicate through the neighbor base stations. The mobile unit uses the neighbor list to monitor signals from neighbor base stations when the mobile unit enters the coverage area of the neighbor base station. Cellular systems may have other types of overhead messages. It is well known in the art that many different parameters required to establish and maintain communication between a mobile unit and a base station may be included in an overhead message.

[0036] Overhead messages are generally received and processed by the mobile unit when the mobile unit is not busy or is not attempting to connect the call (ie, when the mobile unit is "idle"). Is done. The term idle is somewhat misleading because mobile stations can be very busy during idle.

During the idle state, the mobile station wakes up periodically, listens to the paging channel and processes messages on that channel. Over time, the mobile station may wake up periodically and listen to the paging channel, and the overhead message may remain the same. Waking up the mobile station only to determine that the overhead message is the same as the previously decoded previous message in terms of saving and using battery power,
Since it is not preferable to have the overhead message received and decoded, the sequence number is transmitted together with the overhead message. When the mobile station wakes up, the mobile station receives the signature of the overhead message received later, and determines whether to receive the overhead message while the mobile station is waked up. In many instances, the mobile unit goes back to sleep after receiving the signature. The reason is that the received signature has the same sequence number as the sequence number received when the mobile unit last waked up.

The mobile unit performs the listening function because listening for overhead messages requires a certain amount of power and the listening function is performed frequently (such as once every second). Limiting the amount of time spent reduces the overall power consumption of the mobile unit, and thus increases the life of any battery or other power storage system utilized by the mobile unit. In many cases, significant power savings result because the overhead messages remain the same for a significant period of time.

FIG. 3 illustrates a process for updating an overhead message for an embodiment having a forward link having the structure shown in FIG. 2 according to the present invention. Referring to FIG. 3, the overhead message is modified at step 302 at BS 210. In step 304, a signature is generated for the modified overhead message at BS 210.

The signature can be generated by hashing the message using a well-known hashing function that generates a 16 or 32 bit signature. Hashing the message and generating the signature can be performed by a signature generator using well-known computational logic (not shown) or a general-purpose microprocessor (not shown), There is no need to explain. One skilled in the art will recognize that other forms of logic not described herein may be used to generate the signature. The bit length of the signature depends on the system requirement that two consecutive messages separate different signatures (ie, avoid collisions). There is a limited but small probability that two different consecutive messages may share the same signature. The reason is that hashing only functions to compress the message space into a smaller signature space, and more than one message may have the same signature.

If two consecutive messages are different, but hashing produces the same signature for both, then at step 304, a signature different from the predetermined number of previous message signatures is generated. Until the hashing may be repeated using a random number. Alternatively, the signature can be generated by incrementing a counter.

In step 306, the MU 202 wakes up and listens. In step 308, BS 210 sends the signature to MU 202. At step 310, MU 202 receives the signature. In step 312, MU 202 retrieves the previous signature from memory (not shown). In step 312, the MU 202 executes step 3
The signature received at 10 is compared with the previous signature. The circuits or signature comparison elements required to perform the comparison in step 312 can be implemented by various components including microprocessors, as well as combinational logic circuits and other logic circuits. If the signature received in step 310 is the same as the previous signature, step 314
At, the MU 202 returns to sleep. Step 31
If the signature received at 0 is different from the previous signature, then at step 316, the MU 202 remains awake and listens to the message. After receiving the message, the MU 202 updates the operating parameters of the MT 204 so that it can effectively communicate with the system 200.

[0043] The overhead message structure on the paging channel may follow the structure required by a technique known as slotted paging. Slotted paging is useful for reducing power consumption by mobile units. Further information on slotted mode operation was issued on February 21, 1995,
No. 5,392,287, assigned to the assignee of the present invention and entitled "Apparatus and Method for Reducing Power Consumption of Mobile Communication Receivers," which is hereby incorporated by reference. It has been incorporated.

FIG. 4 generally illustrates the structure of a forward link according to another embodiment of the present invention. A forward link is a data stream having a periodic cycle, the data stream including a forward data channel and a multiplexed paging channel. The paging channel contains an overhead message capsule. In the embodiment shown in FIG. 4, the overhead message capsule is 4
Sent during a period having a duration of 00 milliseconds. In other embodiments, this period may be of other duration.

FIG. 5 shows a process for updating an overhead message for another embodiment having a forward link having the structure shown in FIG. 4 according to the present invention. Referring to FIG. 5, the overhead message is modified at step 502 at BS 210. In step 504, the MU 202 wakes up and listens. In step 506, the BS
Sends a message to MU 202, and MU 202 receives this message. In step 508, the MU
202 generates a signature for the message using a hashing function as described with respect to process 300 in FIG.

The hashing of the message to generate the signature can be performed by a signature generator using well-known computational logic (not shown) or a general purpose microprocessor (not shown), There is no need to explain in detail here. One skilled in the art will recognize that other forms of logic not described herein may be used to generate the signature.

In step 512, the MU 202
Retrieve the previous signature from the storage (not shown) of the MU 202. In step 512, the MU 20
2 compares the signature generated in step 508 with the previous signature. The circuits or signature comparison elements required to perform the comparison in step 512 can be implemented by various components including microprocessors, as well as combinational logic circuits and other logic circuits. If the signature generated in step 508 is the same as the previous signature,
In step 514, the MU 202 returns to sleep. If the signature generated in step 508 differs from the previous signature, in step 516, the MU 202 updates its operating parameters with the information contained in the message received in step 506.

Generation and reception of CDMA signals are described in US Pat. No. 4,401,307 entitled "Spread Spectrum Multiple Access Communication System Using Satellite or Terrestrial Repeater" and "Systems for Generating Waveforms in CDMA Cellular Telephone Systems". US Patent 5,103,45 entitled "Method"
No. 9, both of which are assigned to the assignee of the present invention and incorporated herein by reference.

Demodulating multiple signals is described in US Pat. No. 5,490,165 entitled “Assigning Demodulation Elements in a System Capable of Receiving Multiple Signals” and “Diversity Receivers in CDMA Cellular Telephone Systems”. US Patent No. 5,109,390, entitled
Both US patents are assigned to the assignee of the present invention and are incorporated herein by reference.

Although the present invention has been described with reference to particular embodiments, it will be understood that various modifications and changes can be made by those skilled in the art without departing from the spirit and scope of the invention. The invention is not to be limited by the foregoing illustrative details, but is to be defined by the claims.

[Brief description of the drawings]

FIG. 1 is a block diagram of a wireless communication system according to a preferred embodiment of the present invention.

FIG. 2 shows a structure of a forward link of a wireless communication system according to the present invention.

FIG. 3 shows a process for communicating overhead messages using the structure of the forward link illustrated in FIG.

FIG. 4 shows another structure of a forward link of a wireless communication system according to the present invention.

FIG. 3 illustrates another process for communicating overhead messages using the structure of the forward link illustrated in FIG.

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Matthew S. Grob 92037, California, United States, La Jolla, Bordeaux Avenue 2757 F-term (reference) 5K067 AA42 AA44 BB02 DD27 DD51 EE02 EE10 EE16 FF02 GG11 GG21 HH22 HH23 HH24

Claims (62)

[Claims] 1. A method of communicating a message to a mobile station over a wireless communication system providing access to a distributed data network, comprising: providing a series of messages, providing a particular signature for each particular message; A method comprising comparing a particular signature for a message with at least one signature. 2. The method of claim 1, further comprising receiving a specific signature for a specific message. 3. The method of claim 1, further comprising: receiving a particular signature for a particular message, and sleeping after receiving the particular signature. 4. The method of claim 1, further comprising: receiving a particular signature for a particular message; and, after receiving the particular signature, sleeping if the particular signature matches a corresponding signature from the at least one signature. Method. 5. The method further comprising: receiving a specific signature for a specific message, sleeping after the specific signature matches a corresponding signature from the at least one signature, and transmitting the specific message after receiving the specific signature. The method of claim 1, including: wherein sleep occurs while a particular message is being transmitted. 6. The method of claim 1, further comprising: receiving a specific signature for each specific message; and sleeping if each specific signature matches a corresponding signature from the at least one signature. 7. The method further comprising: receiving a specific signature for each specific message, sleeping if each specific signature matches a corresponding signature from the at least one signature, and transmitting each specific message. 2. The method of claim 1, wherein the method occurs while each particular message is being transmitted. 8. The method of claim 1, further comprising: receiving a particular signature for a particular message; and listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature. 9. The method further comprising: receiving a particular signature for a particular message; and listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature, only until a particular message is received. The method of claim 1 wherein listening is performed. 10. Receiving a particular signature for a particular message, listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature, and listening only until the particular message is received. The method of claim 1, further comprising the step of sleeping after a particular message is received. 11. Receiving a particular signature for a particular message, listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature, sleeping after the particular message is received, and after sleeping The method of claim 1, further comprising the step of waking up. 12. Receiving a particular signature for a particular message, listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature, sleeping after the particular message is received; 2. The method of claim 1, further comprising waking up after a two second sleep. 13. Receiving a particular signature for a particular message at a mobile station, listening to the particular message at the mobile station if the particular signature does not match a corresponding signature from the at least one signature, wherein the particular message is received. The method of claim 1, further comprising the step of sleeping at the mobile station later. 14. The method of claim 1, further comprising receiving a specific signature for each specific message. 15. The method of claim 1, further comprising: receiving a specific signature for each specific message; and listening for specific messages of the specific signature that do not match a corresponding signature from the at least one signature. 16. The method further comprising: receiving a particular signature for each particular message; and listening for a particular message of the particular signature that does not match a corresponding signature from the at least one signature, wherein only listening until the particular message is received. The method of claim 1 wherein: 17. The method of claim 17, further comprising: receiving a specific signature for each specific message, listening for a specific message of a specific signature that does not match a corresponding signature from the at least one signature, and sleeping after the specific message is received. The method of claim 1. 18. Receiving a specific signature for each specific message, listening for specific messages of a specific signature that does not match a corresponding signature from the at least one signature, and listening only until a specific message is received; The method of claim 1, further comprising sleeping for 5.2 seconds after a particular message is received. 19. Receiving a particular signature for each particular message, listening for a particular message of a particular signature that does not match a corresponding signature from the at least one signature, listening only until the particular message is received, The method of claim 1, further comprising the step of sleeping after a particular message is received and waking up after sleep. 20. Receiving a specific signature for each specific message, listening for specific messages of a specific signature that does not match a corresponding signature from the at least one signature, and listening only until a specific message is received; The method of claim 1, further comprising: sleeping after a particular message is received; and wake up after 5.2 seconds of sleep. 21. A specific signature for each specific message is received at a mobile station, and a specific message of a specific signature that does not match a corresponding signature from the at least one signature is listened to at the mobile station until a specific message is received. The method of claim 1, further comprising the step of: only listening, sleeping at the mobile station after the particular message is received, and wake-up at the mobile station after sleep. 22. Receiving a particular signature for each particular message at a mobile station, listening at the mobile station for a particular message of a particular signature that does not match a corresponding signature from the at least one signature, until a particular message is received. The method of claim 1, wherein only listening is performed, sleeping at the mobile station after the particular message is received, and waking up at the mobile station after a 5.2 second sleep. 23. A specific signature for each specific message is received at a mobile station, wherein the specific signature for each specific message is transmitted by a wireless communication system, and the specific signature does not match a corresponding signature from the at least one signature. A specific message of the signature is listened to at the mobile station, and the listening is performed only until the specific message is received.The specific message is transmitted by the wireless communication system, and sleeps at the mobile station after the specific message is received. The method of claim 1, further comprising wake-up at the mobile station after sleep. 24. A specific signature for each specific message is received at a mobile station, wherein the specific signature for each specific message is transmitted by a wireless communication system and the specific signature does not match a corresponding signature from the at least one signature. A specific message of the signature is listened to at the mobile station, and the listening is performed only until the specific message is received.The specific message is transmitted by the wireless communication system, and sleeps at the mobile station after the specific message is received. 5. The method of claim 1, further comprising: waking up at the mobile station after a two second sleep. 25. Receiving a particular signature for each particular message, listening for a first particular message of a particular signature that does not match a corresponding signature from the at least one signature, and corresponding signature from the at least one signature. Listening for a second specific message with a specific signature that does not match the following, wherein listening is performed until a second specific message is received, and listening for the second specific message after listening to the first specific message. The method of claim 1, wherein the method is performed. 26. Receiving a particular signature for each particular message, listening for a first particular message of a particular signature that does not match a corresponding signature from the at least one signature, and corresponding signature from the at least one signature. Listening for a second specific message with a specific signature that does not match with, listening until a second specific message is received, listening for a second specific message after listening to the first specific message, The method of claim 1 further comprising the step of sleeping after two specific messages have been received. 27. Receiving a specific signature for each specific message, listening for a first specific message of a specific signature that does not match a corresponding signature from the at least one signature, and corresponding signature from the at least one signature. Listening for a second particular message of a particular signature that does not match with, listening for a second particular message after listening for the first particular message, and for a particular signature that does not match a corresponding signature from the at least one signature Listening for a third specific message, listening for a third specific message after the second specific message, listening for a third specific message until a third specific message is received, 3 specific messages The method of claim 1, further comprising the step of sleep after chromatography di is received. 28. Receiving a particular signature for each particular message, listening for each particular message of a particular signature that does not match a corresponding signature from the at least one signature, and matching a corresponding signature from the at least one signature. The method of claim 1, further comprising: stopping listening when there are no more messages of a particular signature that do not exist; and sleeping after stopping listening. 29. Receiving a particular signature for each particular message, listening for each particular message of a particular signature that does not match a corresponding signature from the at least one signature, and matching a corresponding signature from the at least one signature. The method of claim 1, further comprising the steps of: stopping listening when there are no more messages of a particular signature not to sleep; sleeping after stopping listening; and wake-up after sleep. 30. Receiving a specific signature for each specific message, listening for each specific message of a specific signature that does not match a corresponding signature from the at least one signature, and matching a corresponding signature from the at least one signature. The method of claim 1, further comprising: stopping listening when there are no more messages of a particular signature that do not, sleeping after stopping listening, and waking up after 5.2 seconds of sleep. 31. A specific signature for each specific message is received at a mobile station, wherein the specific signature for each specific message is transmitted by a wireless communication system and the specific signature does not match a corresponding signature from the at least one signature. Listening for each specific message of the signature at the mobile station, stopping listening if there are no further messages of the specific signature that do not match the corresponding signature from the at least one signature, each specific message being transmitted by the wireless communication system The method of claim 1, further comprising the steps of: sleeping at the mobile station after stopping listening; and wake-up at the mobile station after sleep. 32. A specific signature for each specific message is received at a mobile station, wherein the specific signature for each specific message was transmitted by a wireless communication system, and the specific signature does not match a corresponding signature from the at least one signature. Listening for each specific message of the signature at the mobile station, stopping listening if there are no further messages of the specific signature that do not match the corresponding signature from the at least one signature, each specific message being transmitted by the wireless communication system The method of claim 1, further comprising the step of: sleeping at the mobile station after stopping listening; wake-up at the mobile station after 5.2 seconds of sleep. 33. The method of claim 1, further comprising wake-up at the mobile station and receiving at the mobile station a particular signature for the particular message. 34. Waking up at the mobile station, receiving at the mobile station a particular signature for a particular message, and listening for the particular message if the particular signature does not match a corresponding signature from the at least one signature. The method of claim 1, wherein the listening is performed only until a specific message is received. 35. The mobile station wakes up, receives a specific signature for a specific message at a mobile station, and listens for the specific message if the specific signature does not match a corresponding signature from the at least one signature, wherein the specific message is The method of claim 1, wherein listening is performed only until received, and further comprising the step of sleeping after a particular message is received. 36. Wake up at the mobile station, receive at the mobile station a specific signature for each specific message, listen for a specific message of a specific signature that does not match a corresponding signature from the at least one signature, and receive the specific message. The method of claim 1, wherein the listening is performed only until a specific message is received, and further comprising a step of sleeping after a specific message is received. 37. Waking up at the mobile station, receiving at the mobile station a specific signature for each specific message, listening for each specific message of a specific signature that does not match a corresponding signature from the at least one signature; The method of claim 1, further comprising: stopping listening if there are no more messages of a particular signature that do not match a corresponding signature from the two signatures; and sleeping at the mobile station after stopping the listening. 38. The method of claim 1, wherein the series of messages is a series of overhead messages. 39. The method of claim 1, wherein the series of messages are transmitted periodically by a wireless communication system. 40. The method of claim 1, wherein the series of messages is transmitted aperiodically by a wireless communication system. 41. The method of claim 1, wherein the series of messages is sent to at least one mobile station. 42. The method of claim 1, wherein each message is embedded in a message capsule having a plurality of messages. 43. The method of claim 1, wherein providing a particular signature for each particular message includes hashing each message. 44. The step of providing a particular signature for each particular message includes hashing each message to generate a first hash, wherein the hashing step comprises the steps of: Rehashing the arbitrary message if it matches at least one corresponding signature from the at least one signature, wherein the at least one corresponding signature provides a specific signature for each specific message 2. The method of claim 1, wherein the method has been generated within a time period _TDelta prior to initiating the step. 45. Providing a particular signature for each particular message includes hashing each message to generate a first hash, wherein the hashing step comprises the steps of: Adding a random value to a first hash if matched with at least one corresponding signature from the at least one signature, wherein the at least one corresponding signature includes a specific signature for each specific message. The method of claim 1, wherein the method has been generated within a time period _TDelta prior to initiating the providing step. 46. The step of providing a particular signature for each particular message includes hashing each message to generate a first hash, wherein the hashing step comprises the steps of: Rehashing any of the messages with a random value if matched with at least one corresponding signature from the at least one signature, wherein the at least one corresponding signature is for each particular message The method of claim 1, wherein the method has been generated within a time period _TDelta prior to commencing a step of providing a particular signature. 47. The step of providing a particular signature for each particular message includes hashing each message to generate a first hash, wherein the hashing step comprises the steps of: Rehashing any of the messages with a random value if matched with at least one corresponding signature from the at least one signature, wherein the at least one corresponding signature is for each particular message The method of claim 1, wherein the time period T _Delta is longer than the maximum allowed sleep time of any mobile station communicating with the wireless communication system, wherein the time period T _Delta is generated within a time period T _Delta prior to commencing the step of providing a particular signature. The described method. 48. The method of claim 1, wherein providing a particular signature for each particular message includes hashing each message to generate a 16-bit value for the particular signature. 49. The method of claim 1, wherein providing a particular signature for each particular message includes hashing each message to generate a 32-bit value for the particular signature. 50. The method according to claim 1, wherein providing a specific signature for each specific message includes applying a value stored in a counter to the specific signature.
The described method. 51. The method of claim 1, wherein providing a particular signature for each particular message comprises incrementing a counter and applying a value stored in the counter to the particular signature. 52. Providing a particular signature for each particular message includes: incrementing a counter if any message does not match a corresponding first message;
2. The method of claim 1, wherein the message is generated at a time prior to initiating the step of providing a series of messages, and includes the step of applying a value stored in the counter to the particular signature. 53. The method of claim 1, wherein one of the series of messages includes an overhead message indicating base station parameters in the wireless communication system. 54. One of the series of messages includes an overhead message indicating base station parameters in the wireless communication system, wherein the base station parameters include system parameters, access parameters, channel list parameters, and neighbor list parameters. The method of claim 1, wherein the method comprises: 55. The method of claim 1, wherein one of the series of messages includes an overhead message indicating system-wide parameters of the wireless communication system. 56. One of the series of messages includes an overhead message indicating system-wide parameters of the wireless communication system, wherein the system-wide parameters include system parameters, access parameters, channel list parameters, and neighbor list parameters. The method of claim 1, wherein 57. The method of claim 1, further comprising receiving a series of messages at a mobile station. 58. The method of claim 1, further comprising receiving a series of messages at the mobile station, wherein providing a specific signature for each specific message includes hashing each message at the mobile station. . 59. The method further comprising receiving at the mobile station any one of a series of messages, wherein providing a particular signature for each particular message comprises hashing each message at the mobile station to obtain a Generating a first hash, the hashing step comprising: using the random value if the first hash of any message matches at least one corresponding signature from the at least one signature. 2. The method of claim 1 wherein said at least one corresponding signature is generated within a time period T _Delta prior to initiating the step of providing a particular signature for each particular message. the method of. 60. The mobile station further comprising receiving any one of a series of messages, wherein providing a particular signature for each particular message includes hashing each message at the mobile station to generate a respective signature for each message. Generating a first hash, the hashing step comprising: using the random value if the first hash of any message matches at least one corresponding signature from the at least one signature. wherein the step of re-hashing the message, wherein the at least one corresponding signature, which has been generated in the previous period T _Delta starting the step of providing a specific signature for each particular message, the period T _Delta Is any communicating with the wireless communication system Allowed longer than the maximum sleep time The method of claim 1 of the mobile station. 61. Providing at least one stored message at a mobile station, further comprising receiving a series of messages at the mobile station, wherein the at least one stored message each corresponds to a message in the series of messages. Providing the particular signature for each particular message includes hashing each message at the mobile station to generate a first hash of each message, wherein the hashing comprises: Re-hashing the arbitrary message using a random value if a first hash matches at least one corresponding signature from the at least one signature, wherein the at least one corresponding signature comprises: Specific message It has been generated in the previous period T _Delta starting the step of providing a specific signature for the period T _Delta is longer than the allowed maximum sleep time for any mobile station in communication with a wireless communication system, A corresponding message from the series of messages received at the mobile station if the particular signature of the corresponding message does not match the corresponding signature from the at least one signature; 2. The method of claim 1, further comprising the step of: 62. Providing at least one stored message at a mobile station, further comprising receiving a series of messages at the mobile station, wherein the at least one stored message each corresponds to a series of messages. A corresponding message from the series of messages received at the mobile station if the specific signature of the corresponding message does not match the corresponding signature from the at least one signature. 2. The method of claim 1, further comprising the step of replacing any messages from said messages.