System for dynamic process assignment in a local area network and method therefor

A system (10) for dynamic process assignment among a plurality of devices (40) includes an initial coordinator (38), a requesting device (60), and a resource device (62). The initial coordinator (38) includes a list of available resources (56) for each device of the plurality of devices (40). The requesting device (60) requests the use of a desired resource. In response to the request from the requesting device (60), the initial coordinator (38) identifies an available resource associated with one of the plurality of devices (40) for use by the requesting device (60) as the desired resource.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates in general to wireless communication systems and in particular to wireless communication systems incorporating dynamic process assignment.

2. Description of the Related Art

Short-range wireless communication and personal area networks will soon proliferate in common household products as well as mobile business products. Currently many products that have wireless capability are incompatible. Short-range wireless local area network (WLAN) protocols such as Bluetooth, HomeRF, and IEEE 802.11 provide an avenue towards compatibility. These short-range WLAN protocols operate at lower power and over shorter distances. These short-range WLAN protocols generally use unlicensed spectrum and require minimal coordination with the secondary communication protocol of the device (e.g., GSM, IS-95, IS-136, ReFLEX , etc.).

Short-range wireless communication can be, for example, provided using an Infrared Data Association (IrDA) communication standard. IrDA is a point-to-point, narrow angle (30 degree cone), ad-hoc data transmission standard designed to operate over a distance of zero (0) to one (1) meter and at speeds of 9600 bits per second to 16 Mega bits per second. Similarly, the short-range communication can be provided using a Bluetooth communication standard. Bluetooth is a short range, point-to-multipoint voice and data transfer standard designed to operate over a nominal distance of ten (10) centimeters to ten (10) meters, but can be extended to one hundred (100) meters by increasing transmit power. Bluetooth operates in the 2.4 Gigahertz radio frequency range.

Short-range WLAN protocols such as IrDA and Bluetooth technology allow for the replacement of the many proprietary cables that connect one device to another with one universal short-range radio link. Short range WLAN protocol technology could replace the cumbersome cables used today to connect a laptop to a cellular telephone or between other devices such as printers, personal digital assistants, desktops, fax machines, keyboards, joysticks or virtually any other digital device. Refrigerators, microwave ovens, dish washers, laundry washers & dryers, stereo, television, digital video disks, video games, lighting, irrigation, cooling and heating systems among others may also take advantage of such short-range radio links.

Potential applications of these low-power, short-range, protocols are wireless connection of peripherals devices, high-speed data transfers to desktop computers and wireline networks, and establishment of short-range ad hoc networks between similar wireless communication devices. Two or more units sharing the same channel is called an ad hoc network. In an ad hoc network one of the units functions as the master while the others function as slaves. For example, in a Bluetooth system, up to seven active slaves can exist in an ad hoc network but many more can remain locked to the same master in a so-called parked state. These parked units cannot be active on the channel, but remain synchronized to the master. The master always controls the channel access for both the active and the parked units. The master in a Bluetooth system controls the traffic across the channel using a polling scheme. Once an ad hoc network has been established, master-slave roles can be exchanged. To avoid collisions, communication between two slaves can only be accomplished through the master unit.

Many short-range communication WLANs such as the Bluetooth system further supports scatternets. A scatternet is the combination of two or more ad hoc networks with overlapping coverage area. Each ad hoc network can only have one master. However, a master in one ad hoc network can participate as a slave in another and slaves can also participate in different ad hoc networks on a time division multiplex basis. Ad hoc networks within a scatternet are not time or frequency synchronized. Each ad hoc network uses its own hopping sequence.

The devices participating in an ad hoc network each include different processes capabilities. For example, some have more processing power, some have access to an unlimited power source, and some include a variety of powerful applications. Further, usage profiles vary for each device. For example, printers may have a low usage profile and thus have some additional free computing time. Similarly, the personal computer in an office may have a high usage profile but may be the only device that has a particular application on board. One personal computer may have access to a higher speed modem.

What is needed is a system and method for dynamically assigning processes within a WLAN such as an ad hoc network to optimize the shared capabilities of each individual unit within the network.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 1 , a communication system 10 having devices that operate on a short-range protocol system 14 and preferably on a secondary protocol system 12 is illustrated. The secondary protocol system 12 as shown in FIG. 1 includes a base station 16 with a co-located base transmitter 18 and base receiver 20 covering a wide area range 22 as shown. A typical secondary protocol could be Motorola's ReFLEX messaging protocol.

It will be appreciated by one of ordinary skill in the art that the secondary protocol system 12 , in accordance with the present invention, can function utilizing any wireless RF channel, for example, a one or two-way pager channel, a mobile cellular telephone channel, or a mobile radio channel. Similarly, it will be appreciated by one of ordinary skill in the art that the secondary protocol system 12 can function utilizing other types of communication channels such as infrared channels, audio channels, and local area networks. In the following description, the term secondary protocol system refers to any of the systems mentioned above or an equivalent.

In one embodiment, each of the devices (i.e.: a personal computer 24 , a wireless communication device 26 , a personal digital assistant 28 , a printer 30 , and a computer 32 ) is a device using a short-range WLAN protocol, such as Bluetooth technology. It will be appreciated by one of ordinary skill in the art that the short-range WLAN protocol, in accordance with the present invention, can function utilizing any short-range wireless protocol such as IrDA, HomeRF, and IEEE 802.11. Using the short-range WLAN protocol, each device will establish a list of partners ,

Using the short-range WLAN protocol, a first device, such as the personal computer 24 (User A), and one or more of the potential partner devices (the wireless communication device 26 , the personal digital assistant 28 , the printer 30 , or the computer 32 ) agree to form an ad-hoc network.

This network is defined by a list of active partners stored in Unit A. The list may contain available resources for each device, including battery life, access to wide area networks, application availability, utilization, etc.

FIG. 2 is a block diagram of an ad-hoc network 36 for use within the communication system 10 of FIG. 1 in accordance with the present invention. The ad hoc network 36 , for example, can be a subset of the short-range protocol system 14 of FIG. 1 . The ad hoc network 36 includes a plurality of devices 40 such as the wireless communication device 26 , the personal digital assistant 28 , the printer 30 , and the computer 32 . In one embodiment, as illustrated in FIG. 2 , the ad hoc network 36 further includes a smart network access point 38 . Within the ad hoc network 36 of FIG. 2 , an initial coordinator functions as the master and the plurality of devices 40 function as the slaves. The initial coordinator, for example, can be the smart network access point 38 or alternatively, the initial coordinator can be one of the plurality of devices 40 .

It will be appreciated by one of ordinary skill in the art that each of the plurality of devices 40 in accordance with the present invention, can be a mobile cellular telephone, a mobile radio data terminal, a mobile cellular telephone having an attached data terminal, or a two way pager, such as the Pagewriter 2000X manufactured by Motorola Inc. of Schaumburg, Ill. Similarly, each of the plurality of devices 40 , in accordance with the present invention, can be a printer, a personal computer, or a personal digital assistant. In the following description, the term device refers to any of the devices mentioned above or an equivalent.

It will be further appreciated by one of ordinary skill in the art that the ad hoc network 36 can include only the plurality of devices 40 in one embodiment without the use of the smart network access point 38 . In this alternative embodiment, one or more of the plurality of devices can take the role of initial coordinator or resource manager.

As illustrated in FIG. 3 in an embodiment where the smart network access point 38 functions as the initial coordinator, the smart network access point 38 preferably functions as a transformer from the short-range WLAN protocol to the secondary network 12 such as a local area network (LAN) or a wireless communication system (see FIG. 1 ). It will be appreciated by one of ordinary skill in the art that one of the plurality of devices 40 alternatively can function as the initial coordinator and that the functionality described herein for the smart network access point 38 can equally apply to one of the plurality of devices 40 . The smart network access point 38 includes an ad hoc network interface 42 , a secondary system interface 44 , a processor 46 and a resource management application 48 .

Coupled to the ad hoc network interface 42 and the secondary system interface 44 is the processor 46 utilizing conventional signal-processing techniques for processing received information. Preferably, the processor 46 is similar to the MC68328 micro controller manufactured by Motorola, Inc. of Schaumburg, Ill. It will be appreciated by one of ordinary skill in the art that other similar processors can be utilized for the processor 46 , and that additional processors of the same or alternative type can be utilized as required to handle the processing requirements of the processor 46 .

In a preferred embodiment, the initial coordinator, such as the smart network access point 38 , includes the resource management application 48 coupled to the processor 46 . The smart network access point 38 performs resource management functions within the resource management application 48 using a processor command 50 sent from the processor 46 . The resource management application 48 sends an application response 52 in reply to the processor command 50 . The resource management application 48 preferably includes a resource-tracking list 54 . The resource management application 48 can be hard coded or programmed into the smart network access point 38 during manufacturing, can be programmed over-the-air upon customer subscription, or can be a downloadable application. It will be appreciated by one of ordinary skill in the art that other programming methods can be utilized for programming the resource management application 48 into the smart network access point 38 .

The resource management application 48 preferably is programmed to enable utilization of a required resource from the resource-tracking list 54 . The resource-tracking list 54 includes a plurality of resource information 56 for each of the plurality of devices 40 of the ad hoc network 36 . For example, the plurality of resource information 56 can include device battery life, device battery capacity, device processing power, and access to the secondary network for each of the plurality of devices 40 . The resource management application 48 , in response to the processor command 50 , preferably accesses the resource-tracking list 54 . The resource management application 48 is programmed to identify an available resource from the resource-tracking list 54 using the plurality of resource information 56 stored in the resource-tracking list 54 by using predetermined algorithms, as is well known in the art. The resource management application 48 is preferably programmed with a set of rules identifying the resource to allocate in response to the processor command 50 . When the resource management application 48 identifies the available resource, the resource management application 48 sends the application response 52 to the processor 46 . The processor 46 , in response to receipt of the application response 52 , enables the use of the available resource by the requesting device.

Referring back to FIG. 2 , the present invention provides a novel way of dynamically assigning a particular task to one of the plurality of devices 40 within the ad hoc network 36 . For example, as illustrated in FIG. 2 , the smart network access point 38 can be located in a public place and the plurality of devices 40 can initially be three devices, for example, the personal digital assistant 28 , the printer 30 , and the computer 32 . The smart network access point 38 and each of the plurality of devices 40 preferably operate using one of many secondary, short-range WLAN protocols as described herein. It will be appreciated by one of ordinary skill in the art that the secondary, short-range WLAN protocol, in accordance with the present invention, can function utilizing any short-range wireless protocol such as Bluetooth, IrDA, HomeRF, and IEEE 802.11. When a fourth device, such as the wireless communication device 26 , comes within the range of the smart network access point 38 , it can decide to become part of the ad hoc network 36 . For example, it can request to be a member of the ad hoc network 36 for the purpose of downloading a long electronic mail document 58 (E-mail) originally written in a language other than English. The smart network access point 38 processes the request from the wireless communication device 26 and identity from the resource-tracking list 54 (see FIG. 3 ) of the smart network access point 38 , the available resource to translate the E-mail document 58 . Further it instructs the resource identified to translate the email where to return the translated email.

For example, when the smart network access point 38 has greater resources available (memory, processing power, energy source) than the other plurality of devices 40 , the smart network access point 38 can run the translation application to translate the E-mail document 58 , while still serving the other three devices.

Alternatively, when the capacity of the smart network access point 38 is low but still has enough processing power to download the document into another device such as the wireless communication device 26 but not run the application, the smart network access point 38 can assign the wireless communication device 26 to run the translation application itself to translate the E-mail document 58 .

Alternatively, when both the capacity of the smart network access point 38 and the battery life of the wireless communication device 26 are low, the smart network access point 38 downloads the E-mail document 58 to another device within the ad hoc network 36 that is capable of running the application such as the computer 32 . Once the computer 32 completes the task, it sends the translated document back to the smart network access point 38 , which forwards this information to the wireless communication device 26 . Alternatively, the computer 32 sends the translated document directly to the wireless communication device 26 .

FIG. 4 illustrates one embodiment of the communication between the smart network access point 38 , a requesting device 60 , and a resource device 62 of the ad hoc network 36 . In FIG. 4 , the smart network access point 38 polls the requesting device 60 by transmitting polling signal 66 in an occupied bandwidth. Preferably, this transmission is of a standard Bluetooth 1.0 type transmission or an equivalent. The requesting device 60 , in response, requests a resource 64 that is dynamically selected by the smart network access point 38 . Initially, it is assumed that a polling signal 66 sent from the smart network access point 38 has just arrived at the requesting device 60 and the smart network access point 38 is maintaining the ad hoc network 36 , e.g., polling the plurality of devices 40 (not shown). When a poll by the smart network access point 38 is not scheduled, the requesting device 60 utilizes its internal resources for performing required tasks.

It will be appreciated by one of ordinary skill in the art that alternatively, the initial coordinator, for example the smart network access point 38 or one of the plurality of devices 40 sets the communication between two devices of the ad hoc network and thereafter the two devices communicate directly with each other without the interference of the initial coordinator.

It will be appreciated by one of ordinary skill in the art that the transmission, in accordance with the present invention, can function utilizing any short-range wireless protocol such as IrDA, HomeRF, and IEEE 802.11. The requesting device 60 then sends a resource request signal 68 to requests the usage of a resource from the ad hoc network 36 to the smart network access point 38 . The smart network access point 38 identifies the available resource within the ad hoc network 36 and sends a polling resource signal 70 to the resource device 62 to confirm use of the selected resource of the resource device 62 . The resource device 62 then sends a confirmation signal 72 to the smart network access point 38 . When the smart network access point 38 finds an acceptable resource, the smart network access point 38 sends an acknowledgement signal 74 acknowledging the request of the requesting device 60 including identification of the resource device 62 . When the smart network access point 38 finds the resource identified as unacceptable, the smart network access point 38 will ideally search the resource-tracking list 54 for the best alternative, which is then sent to the requesting device 60 .

FIG. 5 is a flow chart illustrating the one embodiment of the operation of the ad hoc network 36 of FIG. 2 in accordance with the present invention. In Step 76 , a wireless connection is formed between two devices using one a WLAN protocol. Next, in Step 78 , the two devices have stored in memory a common application. Alternatively, one or both devices can have access to the common application via the secondary protocol system 12 . Next, in Step 80 , one of the devices decides to run the common application. Next, in Step 82 , both devices set a decision counter to zero. Next, in Step 84 , the available excess energy of the two devices is compared. For example, one of the devices can have access to an unlimited power source. In this case, the use of this unlimited power source overrides the currently available energy capacity of the other device. In Step 86 , when the battery life of the first device (D 1 ) is lower than the second device (D 2 ), the counter of D 1 is incremented by one. In Step 88 , when the battery life of D 1 is greater than the battery life of D 2 , the available capacity of the two devices is compared. In Step 90 , when the capacity of D 1 is lower than the capacity of D 2 , the counter of D 1 is incremented by one. In Step 92 , when the capacity of D 1 is greater than the capacity of D 2 , the processing power of the two devices is compared. In Step 94 , when the capacity of D 1 is lower than the capacity of D 2 , the counter of D 1 is incremented by one. When the processing power of D 1 is greater than the processing power of D 2 in Step 92 , and when the counter of D 1 has been incremented by one in Steps 86 , 90 , and 94 , next, in Step 96 , the final counter value is calculated. Next, in Step 98 , the counter value of D 1 is compared to the counter value of D 2 . In Step 100 , when the counter value of D 1 is lower than the counter value of D 2 , D 1 is used to run the common application. In Step 102 , when the counter value of D 1 is higher than the counter value of D 2 , D 2 is used to run the common application. The process then resets to begin again at Step 76 .

To illustrate the method of the present invention, consider a video cellular telephone, which has an application to perform the MPEG4 video compression and decompression. The raw video signal can require a data rate (bandwidth) of several hundred kilobits per second (kbps). When compressed, the video signal can require as little as 28.8 kbps, depending upon the quality and size of the video image. For macro-cellular connections (i.e.: GSM cellular network) the compressed signal is transmitted over the wireless channel for bandwidth efficiency, in order to support many users. The videophone performs both MPEG4 compression and decompression for transmitting and receiving the video signal. The same phone can also be used on a WLAN, which can support higher bandwidths, and typically fewer users. When the video phone connects with the smart network access point 38 using the WLAN protocol, the phone and the smart network access point 38 can communicate regarding available bandwidth, MIPs capabilities and devices' processors, and user battery status. As a result, the devices can make a decision for the smart network access point to do the processing intensive MPEG4 video compression and decompression and then transmit the uncompressed video signal to the user's device with a higher bandwidth WLAN protocol. This saves battery power and potentially speeds up the video processing at the expense of consuming WLAN bandwidth and processing resources of the smart network access point. The decision of the smart network access point to perform the video compression and decompression can be made on a frame by frame basis, so the smart network access point 38 can continue to handle other processes intermittently.

Although the invention has been described in terms of preferred embodiments, it will be obvious to those skilled in the art that various alterations and modifications may be made without departing from the invention. Accordingly, it is intended that all such alterations and modifications be considered as within the spirit and scope of the invention as defined by the appended claims.