CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority from U.S. provisional application No. 60/337,241 and filed on Nov. 30, 2001 which is incorporated by reference as if fully set forth.

FIELD OF THE INVENTION

The present invention relates to wireless communications. More particularly, the present invention relates to cognitive radio and the employment of multiple classes of cognitive radio modelers in wireless communications and method and apparatus making optimal use of the radio channel based on information from the cognitive modelers.

BACKGROUND

Cognitive Radio involves three layers: cognition models, a language for communicating the descriptors of the cognition models and a processor for analyzing cognition descriptors and making decisions. The invention encompasses three classes of cognition models.

SUMMARY OF THE INVENTION

Three classes of cognition models are proposed as follows:

1) Radio Environment models,

2) Mobility models and

3) Application/User Context models.

Radio environment represents the physical aspects, mobility predicts the future positions of a user terminal while the application represents the present state and dynamics of each of these application processes within itself and between multiple application processes.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be understood from the following description and drawings in which like elements are designated by like numerals and, wherein:

FIG. 1

is a block diagram of a user equipment (UE) embodiment of the present invention;

FIG. 2

is a block diagram of a network embodiment of the present invention;

FIG. 3

outlines the physical model attributes of the present invention;

FIG. 4

depicts the mobility modeler attributes of the present invention; and

FIG. 5

describes the application context models of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The invention proposes three classes of cognition models:

1) Radio Environment models,

2) Mobility models and

3) Application/User Context models.

Radio Environment models represent the physical aspects of the radio environment, such as shadowing losses, multi-path propagation, interference, noise levels, etc.

Mobility models represent users motion, in terms of geo-coordinates and/or logical identifiers, such as street names etc. as well as speed of movement of user terminals, etc. The Mobility models are used for predicting future positions of the user terminal.

Application/User Context represents the application environment that the user is presently in and can be used for predicting the application environment in future time instants. For example, an application context may consist of a user browsing the web using http/tcp/hip protocols, user talking on a voice call, involved in a file transfer, such as music download, etc.

The context model represents the present state and dynamics of each of these application processes per se and between multiple application processes. For example, Internet browsing is often modeled in terms of packet session, packet calls, number, duration and separation of individual packets etc. This represents the context modeling within an application process. The context modeling between multiple application processes consists of representing the dynamics of how users may move from one application process to another, etc.

FIGS. 1 and 2

respectively show embodiments of a user equipment (UE) and a network, based on the principles of cognitive radio and the three types of cognition models described above.

FIG. 1

is an embodiment employing three types of cognition models, while

FIG. 2

is an example of cognitive radio network, employing three types of cognition models and a cognitive radio resource manager. Tables 1 (FIG.

2

), 2 (

FIG. 3

) and 3 (

FIG. 4

) detail the attributes of the physical, mobility and context modelers respectively. The three parts are independent. Systems can be built using one or more of the three classes of models.

FIG. 1

shows the user UE

10

comprising a geographic data base

12

, a physical modeler

14

and a mobility modeler

16

. The geographic database stores geo-locations and location related attributes for the geo-locations which may include land formations, such as hills, mountains, etc., buildings, trees, atmospheric attributes, etc. The physical modeler

14

provides radio related attributes such as multi-path attributes, shadowing attributes and Doppler attributes associated with the geographic locations.

The mobility modeler

16

provides information associated with UEs such as their geo-coordinates, velocity, road topology along which UEs may be traveling including traffic lights, etc. and traffic density. This data is transferred to the channel processor

18

which prepares the data for transmission to modem

26

, i.e. maps the application data to the channel and identifies received data and directs the received data to the proper destination. The data, at baseband, is modulated with an appropriate radio frequency at

28

and transmitted through antenna apparatus

30

for communication with the network.

The applications which may include internet browsing, speech activity e-mail, instant messaging, etc. are provided to the application context modeler

22

and application processor

24

for modeling. For example, internet browsing is often modeled in terms of packet session, packet calls, number, duration and separation of individual packets, etc. This data is provided to the channel processor

18

for subsequent transmission, in the manner described hereinabove with regard to mobility and physical modelers

14

and

16

, respectively. The various applications handled by application circuitry

20

, are shown in FIG.

5

. The application processor

24

incorporates the coding and processing for forwarding data to the proper destination, for example, providing the necessary coding and processing for internet browsing (TCP/IP), voice communication, images, short message service (SMS); and multimedia service (MMS).

FIG. 2

shows a network unit, wherein like elements are designated by like numerals and further including a cognitive radio resource controller (RRC) respectively coupled to the application context, physical and mobility modelers

22

,

14

, and

16

. The RRC

32

normally controls optimal transmission of packets over the air and further manages spectral resources to ensure that quality of service (QoS) is maintained. User traffic and radio channel performance is routinely monitored for purposes of controlling air interface parameters. Air bandwidth allocation and revenue maximization are controlled, together with carrier policies, to assure QoS is judiciously applied to generate revenue based on usage charges, subscription, or other subscriber policies. The RRC utilizes information from the modelers

14

,

16

and

22

to make more efficient use of the radio channel.

Typically, the physical modeler

14

makes a number of measurements of the radio channel. For example, physical modeler

14

measures the interference levels and/or noise levels; measures the channel impulse response; and estimates the multipath characteristics. These characteristics include the total energy, the delay spread, the number of significant paths (also called ‘fingers’) and the locations of these significant paths; Doppler shifts; the large scale path losses, etc. The art of these measurements is well established in the literature. In addition, the physical modeler

14

may also determine the location of one or more UEs. When the modeler

14

is implemented in the UE, then it may determine its own location, whereas if it is implemented in the Network, it may determine the locations of more than one UE. The UE may determine its own location by a global positioning system (GPS), not shown for purposes of simplicity, or Network assisted GPS. The Network may determine the locations of UEs employing Base Station triangulation principles.

The location information may be related to a local geographic map and related to roads, intersections, landmarks, buildings, hills, parks, etc. Based on such relations, the physical radio environment may be characterized as being indoor, dense urban, urban, rural, hilly, highway etc. These measurements form the parameters of the physical modeler

14

.

Similarly, the mobility modeler

16

estimates the future locations of the UE or UEs in relation to a geographic map. For instance, if the UE is located on a highway and is moving at a certain velocity, then its future positions can be estimated. In case the UE is located near an intersection in a downtown area, then the road information will provide several alternatives for the future locations with associated probabilities. The set of possible future positions of a UE, together with associated probabilities become the parameters of the mobility modeler

16

.

Finally, the application context is modeled. Depending upon the specific application the user is engaged in, the current and future data rate and QoS requirements can be estimated. For example, assuming the user (UE) is engaged in a voice conversation, then the amount of data generated can be modeled based on general speech characteristics and the voice compression algorithm currently being used. Similarly, if the user is engaged in a web browsing session, the packet flows can be modeled in a statistical fashion. For example, web browsing is typically performed employing TCP/IP protocol, which has a certain structure. As an example, the TCP session is always preceded by a 3-way handshake, involving small amounts of data transfer. This is typically followed by a number of request-response type transactions. The request messages are small in size, whereas the response can be much larger. Similarly, email applications, file transfer protocol (FTP) applications, short message system (SMS) applications, multimedia system (MMS) applications, picture messaging applications, etc. can be characterized by the protocol structure and data statistics. These characteristics form the parameters of the application context modeler

22

.

The various modelers can be implemented in the UE and/or the Network. The network and optionally the UE also implements a so-called cognitive controller, shown as a radio resource controller

32

, which accepts the parameters from modelers

14

,

16

and

22

as inputs and processes them for determining optimal radio performance. Specifically, the cognitive controller (RRC)

32

determines optimal data rates, error correction coding schemes, antenna beam widths, power levels, application queue dimensions, etc. The current radio parameters are accordingly adjusted. In some cases, new processes may be invoked, such as the turning on or off of acknowledged mode of radio data transmission. In such cases, radio parameters are either selected or aborted. The cognitive controller (RRC)

32

in the UE and in the network may be input with local cognition model parameters, as in the case of local optimization in a UE or the network. The cognitive controller (RRC) in the network may also be input with local cognition model parameters as well as cognition model parameters of various UEs, which have been transmitted to the network. In this case, each UE uses one or more of the radio channels and reports the cognition model parameter data. A suitable set of messages and reporting structure is used for the protocol. The network then processes the local as well as remote (i.e., from the UEs) cognition model data and generates various adjustments for optimal or improved performance. While some of these adjustments are affected locally in the network, the others would be transmitted to the concerned UE, using appropriate command protocols. This results in a cognitive radio system, which strives to perform optimally in changing physical, user and application conditions by using the data generated by the various cognition models.