Abstract:
A mobile wireless communication device is provided with an integral transducer used to refresh a random data pool without connection to an external source of new random data.

Description:
BACKGROUND 
     1. Field of Technology 
     This application generally relates to mobile wireless communication devices requiring random data for use in normal device operation. 
     2. Related Art 
     A need for random data in normal operation of mobile wireless communication devices is now common place. For example, secure encrypted communication requires generation of suitable encryption/decryption keys or the like from time to time. Generation of an encryption key may be required for device content (e.g., e-mail, calendar, memo pad, contacts, etc.). Wireless communication via Bluetooth or other similar techniques may also require random data inputs from time to time. It is also known that random data may be used to wipe non-volatile memory. For example, in order to insure erased data on a hard drive is unrecoverable, a technique of writing random data to the drive may be employed. 
     There are known techniques for generating sufficiently random data (e.g., by capturing random mouse movements of a user or the like) at a base station (e.g., a user&#39;s personal computer) and then may derive a key for communication or alternative purposes. This key may be stored on a communications server, desktop PC, as well as the handheld device. The newly captured random data and/or derived key may be transferred to associated devices from time to time when the need arises. 
     However, if a mobile wireless communication device is without an external source of renewable random data (e.g., a plug in connection to the user&#39;s base or desktop computer), one needs to address the need for sufficiently random data to use in the generation of a random pattern (e.g., for encryption key generation). Typically when the stored key or random data becomes out of date and the user has connected his/her device to a base or desktop computer, they may be prompted to move a mouse around randomly for generation of a new random number pool for use as an encryption key (or to be used in generation of such key). 
     A problem to address is how to create the same or approximately equivalent randomness for key creation by random motion once the device no longer connects via serial/USB to the user&#39;s desktop. 
     A similar situation can arise with other peripherals or memory cards which attach to the device that require a method of securing data via a randomly generated pattern for encryption key creation, e.g., secure data (SD) cards, multimedia cards, compact flash, smartcards, Bluetooth accessories, etc. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These and other objects and advantages will be better understood and appreciated in conjunction with the following detailed description of exemplary embodiments taken together with the accompanying drawings, of which: 
         FIG. 1  is an overall system wide schematic view of an exemplary wireless email communication system incorporating a mobile wireless communication device having enhanced internal ability to add randomness to a random data pool maintained therein; 
         FIG. 2  is an abbreviated schematic diagram of hardware included within an exemplary mobile wireless communication device; 
         FIG. 3  is an exemplary abbreviated schematic flow diagram of computer software (i.e., program logic) that may be utilized in the device of  FIG. 2  (e.g., during start-up) to re-initiate an update of random data being maintained in the device; and 
         FIG. 4  is an exemplary abbreviated schematic flow diagram of computer software (i.e., program logic) that may be utilized in the device of  FIG. 2  to interface with an included transducer for generating new random data. 
     
    
    
     DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
     A wireless mobile communication device may include its own integral apparatus/method for generating new random data as needed or desired. 
     For example, such a device may include a data memory storing random data for use in data communication processes (e.g., encrypted secure processes). A transducer integrally carried as part of the mobile communication device can be adapted to produce electrically sensible output related to a physically sensible parameter. The electrically sensible output of the transducer is then captured within the mobile communication device and used to generate new random data and store it in the random data memory based on the electrically sensible output while the physical parameter is randomly varying. 
     The present exemplary embodiments provide a general solution for locally generating random data for the purpose, for example, of generating an encryption key for securing data. 
     This can be accomplished locally on a mobile device if it is equipped with a method to detect, measure, and record random motion (analogous to mouse movement). There are many possible arrangements available to achieve this, e.g.:
         (1) By using an accelerometer or gyroscope type of sensor the user can move the device around by tilting or gesturing in random movement. Also, the device could be placed on a flat surface and the acceleration (translational motion) could be measured (e.g., like mouse movements). The movement may be in a required direction of three dimensional space if the sensor responds preferentially in one direction.   (2) Using optical scanning technique such as with a camera that is integrated with the device, it could work like an optical mouse, i.e., the handheld could be placed on a surface for position tracking.   (3) Using as sources of random input transducers such as ambient light sensor, microphone, digital compass, fingerprint sensor, navigation input sensor devices such as a roller ball, touch screen, joystick, touch pad, etc.   (4) Outputs from different random sources can be further intermixed (e.g., via bit swapping, bit shifting, etc.) before being added to the random data pool.       

     The system may prompt the user to randomly move the device to generate data for creating the new random key data (analogous to a current desktop application). During a set period of time the output of the sensors can be read and this resulting random sensor data can be used to generate random key data. 
     As an alternative, depending on the electrical current draw of the sensor, this could be used continually, or frequently, to harvest randomness from the user. That is, the system could turn on the accelerometer or take a picture every so many seconds to gather randomness that is added to a pool of randomness whenever needed or desired. The process for administering the random pool of data can be notified by the system to intercept sensor data whenever the sensor has been enabled by another application. For example, an accelerometer may be set to detect random device motion based on pre-programmed threshold limits and interrupt the system to read the accelerometer data. 
     These embodiments may be realized in hardware, software or a combination of hardware and software and provide a method for internally adding randomness to wireless communication device. The exemplary embodiment is realized at least in part, by executable computer program code which may be embodied in physical program memory media. 
       FIG. 1  is an overview of an exemplary communication system in which a wireless communication device  100  may be used in accordance with this invention. One skilled in the art will appreciate that there may be hundreds of different system topologies. There may also be many message senders and recipients. The simple exemplary system shown in  FIG. 1  is for illustrative purposes only, and shows perhaps the currently most prevalent Internet email environment. 
       FIG. 1  shows an email sender  10 , the Internet  12 , a message server system  14 , a wireless gateway  16 , wireless infrastructure  18 , a wireless network  20  and a mobile communication device  100 . 
     An email sender  10  may, for example, be connected to an ISP (Internet service Provider) on which a user of the system has an account, located within a company, possibly connected to a local area network (LAN), and connected to the Internet  12 , or connected to the Internet  12  through a large ASP (application service provider) such as America Online™ (AOL). Those skilled in the art will appreciate that the systems shown in  FIG. 1  may instead be connected to a wide area network (WAN) other than the Internet, although email transfers are commonly accomplished through Internet-connected arrangements as shown in  FIG. 1 . 
     The message server  14  may be implemented, for example, on a network computer within the firewall of a corporation, a computer within an ISP or ASP system or the like, and acts as the main interface for email exchange over the Internet  12 . Although other messaging systems might not require a message server system  14 , a mobile device  100  configured for receiving and possibly sending email will normally be associated with an account on a message server. Perhaps the two most common message servers are Microsoft Exchange™ and Lotus Domino™. These products are often used in conjunction with Internet mail routers that route and deliver mail. These intermediate components are not shown in  FIG. 1 , as they do not directly play a role in the invention described below. Message servers such as server  14  typically extend beyond just email sending and receiving; they also include dynamic database storage engines that have predefined database formats for data like calendars, to-do lists, task lists, email and documentation. 
     The Wireless gateway  16  and infrastructure  18  provide a link between the Internet  12  and wireless network  20 . The wireless infrastructure  18  determines the most likely network for locating a given user and tracks the users as they roam between countries or networks. A message is then delivered to the mobile device  100  via wireless transmission, typically at a radio frequency (RF), from a base station in the wireless network  20  to the mobile device  100 . The particular network  20  may be virtually any wireless network over which messages may be exchanged with a mobile communication device. 
     As shown in  FIG. 1 , a composed email message  22  is sent by the email sender  10 , located somewhere on the Internet  12 . This message  22  typically uses traditional Simple Mail Transfer Protocol (SMTP), RFC  822  headers and Multipurpose Internet Mail Extension (MIME) body parts to define the format of the mail message. These techniques are all well known to those skilled in the art. The message  22  arrives at the message server  14  and is normally stored in a message store. Most known messaging systems support a so-called “pull” message access scheme, wherein the mobile device  100  must request that stored messages be forwarded by the message server to the mobile device  100 . Some systems provide for automatic routing of such messages which are addressed using a specific email address associated with the mobile device  100 . In a preferred embodiment, messages addressed to a message server account associated with a host system such as a home computer or office computer which belongs to the user of a mobile device  100  are redirected from the message server  14  to the mobile device  100  as they are received. Messages will typically be encrypted from sender to receiver by utilizing a key that is unique to a given device. Examples of two commonly used methods are the Data Encryption Standard (Triple—DES) and the Advanced Encryption Standard (AES). 
     Regardless of the specific mechanism controlling forwarding of messages to mobile device  100 , the message  22 , or possibly a translated or reformatted version thereof, is sent to wireless gateway  16 . The wireless infrastructure  18  includes a series of connections to wireless network  20 . These connections could be Integrated Services Digital Network (ISDN), Frame Relay or TI connections using the TCP/IP protocol used throughout the Internet. As used herein, the term “wireless network” is intended to include three different types of networks, those being (1) data-centric wireless networks, (2) voice-centric wireless networks and (3) dual-mode networks that can support both voice and data communications over the same physical base stations. Combined dual-mode networks include, but are not limited to, (1) Code Division Multiple Access (CDMA) networks, (2) the Group Special Mobile or the Global System for Mobile Communications (GSM) and the General Packet Radio Service (GPRS) networks, and (3) future third-generation (3G) networks like Enhanced Data-rates for Global Evolution (EDGE) and Universal Mobile Telecommunications Systems (UMTS). Some older examples of data-centric network include the Mobitex™ Radio Network and the DataTAC™ Radio Network. Examples of older voice-centric data networks include Personal Communication Systems (PCS) networks like GSM, and TDMA systems. 
     As depicted in  FIG. 2 , mobile communication device  100  includes a suitable RF antenna  102  for wireless communication to/from wireless network  20 . Conventional RF, demodulation/modulation and decoding/coding circuits  104  are provided. As those in the art will appreciate, such circuits can involve possibly many digital signal processors (DSPs), microprocessors, filters, analog and digital circuits and the like. However, since such circuitry is well known in the art, it is not further described. 
     The mobile communication device  100  will also typically include a main control CPU  106  which operates under control of a stored program in program memory  108  (and which has access to data memory  110 ). CPU  106  also communicates with a conventional keyboard  112 , display  114  (e.g., an LCD) and audio transducer or speaker  116 . A portion of data memory  110 a is available for storing random data needed for device operations. Suitable computer program executable code is stored in portions of program memory  108 a to constitute the internal random addition capability described below. A transducer  118  provides an electrical input to the CPU  106  that corresponds to a randomized physical event. Some examples of possible physical transducers are: an accelerometer; a gyroscopic sensor; a tilt sensor; a movement sensor; optical sensor or scanner; relative position tracking device like a mouse transducer, etc. Those in the art will recognize that the list of possible transducers is virtually unlimited. 
     As those in the art also will appreciate, entry into the process of gathering new random data may be made in any desired way. As earlier noted, it may be effective at all times or at times whenever it is algorithmically determined to be needed or desirable. One other possibility is depicted at  FIG. 3 , where, during normal booting or start-up processes entered at  300 , a test is made at an appropriate point  302  to determine whether the current random data pool in the device is out of date. If so, then the user is suitably prompted at  304  and if the user elects at  306  to update the random data at this time, then the user is further prompted at  308  to take appropriate random physical action that can be sensed by the transducer included as an integral part of the device. For example, the user may be instructed to randomly move the device in three dimensions for the next few (e.g. 15) seconds. After such instruction to the user, then a loop counter N may be set to zero and the GET timed interrupt routine may be initiated at  310 . 
     The GET RANDOM routine  400  illustrated in  FIG. 4  is, in this exemplary embodiment, a timed interrupt routine while active. For example, the timed interrupt may occur at intervals of a few tens of milliseconds or the like during the interval of instructed random physical activity (e.g., 15 seconds). The loop counter N is incremented at  402  and a test is made at  404  to see whether the updating of random data process has yet been completed. If so, then the timed interrupt routine is suitably terminated at  406  (unless, of course, the system is designed so as to run continuously in which the case the just discussed steps may be eliminated). 
     During the process of active updating of random data, the transducer output is read at  408  and then tested at  410  to insure that there is indeed some requested physical activity taking place so as to change the transducer output by at least some predetermined increment from the last sample taken. If so, then the new current transducer output is utilized at  412  in accordance with conventional techniques to determine and store at least one new random data point value R N . As will be appreciated, a suitable random data pool might comprise 64 random bits, 128 random bits, etc. which can dynamically be configured depending on the type of algorithm employed or the required need. The process may determine one or more bits of such data pool at each timed interrupt execution of this routine. The current execution instance of the timed interrupt routine is then exited at  414  until again entered at the end of another elapsed timed interrupt period. 
     As those in the art will appreciate, there may be many variations and modifications of the above described exemplary embodiments which yet retain some or all of the novel features and advantages of these embodiments. Accordingly, all such modifications and variations are intended to be included within the scope of the appended claims.