PRIORITY CLAIMThis Application claims the benefit of the U.S. Provisional Application Ser. No. 60/559,735 filed on Apr. 6, 2004, which is expressly incorporated herein, by reference.
BACKGROUND INFORMATIONBusiness and individuals today rely on mobile computing products/arrangements (“MCPs”, e.g., bar code readers, PDAs, laptops, two-way pagers, mobile phones, digital cameras, mobile optical readers) in a multitude of situations ranging from basic everyday tasks to highly specialized procedures. As the virtues and benefits of utilizing MCPs continue to be realized across increasingly diverse industries, the features and capabilities of these products are expanding at a correspondingly rapid pace. In many industries, MCPs have gone from fashionable accessories to essential business components used by all levels of personnel.
Accordingly, a great need has developed for MCPs to perform complicated tasks quickly, efficiently and reliably. However, as conventional MCPs are fitted with more advanced gadgetry and software features, sacrifices are often made with respect to durability, power management and user-friendliness. While many methods have been devised attempting to resolve these difficulties, MCPs currently continue to suffer from problems of inefficient power usage, complicated operational procedures and on-screen menus, and the inability to tolerate the harsh industrial conditions to which the products may be subjected.
In the ongoing search for solutions to these problems, one aspect of MCPs that has remained overlooked is a product's kinetic state. From an MCP's motions, valuable information may be extracted from which various predetermined procedures directed at accomplishing some useful end or preventing some harmful result may be executed. Therefore, it is desirable to be able to detect, interpret and utilize the movements experienced by MCPs.
SUMMARY OF THE INVENTIONDescribed is a system and method for monitoring a mobile computing Arrangement. The arrangement may include a sensor and a processor. The sensor detects first data of an event including a directional orientation and a motion of the arrangement. The processor compares the first data to second data to determine if at least one predetermined procedure is to be executed. The second data may include a predetermined threshold range of changes in the directional orientation and the motion. If the predetermined procedure is to be executed, the processor selects the predetermined procedure which corresponds to the event as a function of the first data. Subsequently, the predetermined procedure is executed.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 shows an exemplary embodiment of a mobile network according to the present invention.
FIG. 2 shows an exemplary embodiment of a mobile computing product/Arrangement according to the present invention.
FIG. 3 shows an exemplary embodiment of a method for monitoring a mobile computing product/Arrangement according to the present invention.
DETAILED DESCRIPTIONThe present invention may be further understood with reference to the following description and the appended drawings, wherein like elements are provided with the same reference numerals. The present invention relates to an MCP which includes a sensor that monitors the MCP's directional orientation and motion. In particular, the sensor may measure the MCP's acceleration, velocity, or angular velocity in any direction, orientation with respect to the user, the forces on the MCP upon impact, the direction of impact, or any other shocks or movements to which the MCP may be subjected. These measurements may be contrasted with prerecorded movement patterns or predefined levels of acceptable and unacceptable movement. As will be described below, predetermined procedures may then be executed that may be useful in a wide range of applications, including but not limited to abuse indication, power management, gesture input, compensating for undesired motion, display orientation, and security.
FIG. 1 shows an exemplary embodiment of amobile network100 according to the present invention. In this embodiment, themobile network100 may be operating within a Wireless Local Area Network (“WLAN”)40 in an infrastructure mode. Themobile network100 may also include an access point (“AP”)10, a plurality ofMCPs20,25, acommunications network50, aserver60, and aclient computer70. TheMCP20 is height h1 from theground30, and theMCP25 is height h2 from theground30. BothMCPs20,25 are situated on a three dimensional plane in which they may translate, rotate, pivot, accelerate or otherwise be in motion. Those of skill in the art will understand that the exemplary embodiments of the present invention may be used with any mobile network and that themobile network100 is only exemplary.
The WLAN40 may use a version of the IEEE802.11 or a similar protocol. One benefit of using a version of the IEEE 802.11 standard is that existing infrastructures using that standard may be adapted to support the system with minimal modifications. With only a simple software upgrade,most MCPs20,25 supporting that standard may operate according to the present invention. In alternative exemplary embodiments, different wireless protocols or technologies (e.g., Bluetooth, WWAN, WPAN, infrared) may also be utilized.
Referring back to themobile network100, the AP10 may be, for example, a router, switch or bridge that forms the connection between theWLAN40 and thecommunications network50. Coupled to theWLAN40 are theMCPs20,25, and coupled to thecommunications network50 are theserver60 and theclient computer70. Thecommunications network50 is utilized to transmit data between the various components of themobile network100. Thiscommunications network50 can be any network usable to transmit data, such as between microprocessors, and may be a local area network (“LAN”), a wide area network (“WAN”) or the Internet. The range of theMCPs20,25 are restricted only by the extent of thecommunications network50. When thecommunications network50 includes the Internet, the range can be essentially unlimited, as long as the AP10 connected to thecommunications network50 is within range of each of theMCPs20,25. Therefore, the AP10 does not have to physically be in the vicinity of theserver60 or theclient computer70, as it may be remotely located by extending network cabling or through the Internet.
TheMCPs20,25 may be any type of computer or processor based mobile device (e.g., a bar code reader, a PDA, a laptop, a two-way pager, a mobile phone, a digital camera, a mobile optical reader). Since theMCPs20,25 are portable, they are capable of connecting to a wireless network, and are sufficiently small to be easily carried. TheMCPs20,25 may be designed for specific purposes, such as reading barcodes, or may be handheld devices with different purposes, to which various functionalities have been added through separate software modules. In one exemplary embodiment, theMCPs20,25 are based on a multi-purpose personal digital assistant (“PDA”) such as those running the Microsoft Pocket PC 2003 operating system, or similar.
FIG. 2 shows an exemplary embodiment of anMCP20,25 according to the present invention. In this embodiment, theMCP20,25 may include aprocessor110, asensor120, anon-removable memory130, aremovable memory140, and anantennae150. Theprocessor110 is a central processing unit (“CPU”) that executes instructions on measurements taken by thesensor120 and performs procedures such as storing the result in memory or transmitting the result to remote devices through theantennae150. Thenon-removable memory130 is any type of memory component integrated into the electronic architecture of theMCP20,25 and may be temporary (e.g., random access memory, or RAM) or permanent (e.g., a hard-disk drive). Theremovable memory140 may be any type of detachable memory component that may connect to theMCPs20,25 through an expansion interface (e.g., a FLASH interface, a USB interface, a firewire interface, etc.).
In the exemplary embodiment ofFIG. 2, thesensor120 is integrated into theMCPs20,25. Thissensor120 may be a device coupled to an electronic architecture of theMCPs20,25 that dispatches data to a separate memory device, or it may be coupled to at least a portion of another device in the architecture. For instance, in the latter embodiment, thesensor120 may be coupled to a memory arrangement in which event data (e.g., a first data of an event relating to theMCP20,25's movements with values above a certain threshold) is stored. In an alternative exemplary embodiment, thesensor120 may be a separate external device that connects to theMCPs20,25 through an expansion slot (e.g., a sensor with a FLASH, USB, firewire or similar interface).
Thesensor120 may be any type of measurement device capable of monitoring directional orientation and motion, and may be based on, for example, a G-shock sensor, a switch, an accelerometer, a strain gage, a piezo, MEMS technologies, or combinations of the like. The directional orientation may include any angular movement value with respect to at least one three-dimensional axis of theMCPs20,25. The motion may include, for example, a velocity value, an acceleration value, or an angular velocity value. Although thesensor120 may be of any size, thesensor120 is preferably small enough so that any added weight and space occupied on theMCPs20,25 are negligible. Because theMCPs20,25 usually operate on batteries, thesensor120 should also have a low power consumption. In addition, thesensor120 should be durable enough to withstand the abusive environments of which its purpose is to monitor.
Thesensor120 detects changes in the directional orientation and motion of theMCP20,25 and generates the first data. The first data is provided to theprocessor110 which compares the first data to predetermined second data which includes threshold range values. For example, the second data may be a prerecorded rotation of theMCP20,25 by ninety degrees, the detection of which may indicate of the occurrence of an event. The second data may be a maximum height from which theMCP20,25 is dropped. Subsequently, based on the first data, a particular predetermined procedure is selected and executed.
The first data may be retained for each instance where the measurements of thesensor120 are above or below the second data which specifies an acceptable threshold level. Theprocessor110 may also append additional information to the retained first data including sequential numbering of the events, time and date for each event, acceleration data, data corresponding to a status of theMCPs20,25 at the date/time of the event, environmental factors, a direction of the shock, etc.
Depending on the application of the present invention, various predetermined procedures may be performed based on the first data. For example, if desired, the first data may be stored in thenon-removable memory130 and/or theremovable memory140 prior to executing any other procedures. Alternatively, the first data may not need to be stored locally at all, instead it is transmitted in real-time for storage and/or further processing by a central server or a remote device. Such a transmission may be accomplished via the communication arrangement of themobile network100 ofFIG. 1. TheWLAN40 andcommunications network50 comprise the communication arrangement, and theserver60 and theclient computer70 comprise the central server or the remote device.
The foregoing embodiments of themobile network100 and theMCPs20,25 are not to be construed so as to limit the present invention in any way. As will be apparent to those skilled in the art, different types ofMCPs20,25 may be used to communicate over the same data network, as long as they work under compatible protocols. Other configurations with different numbers of MCPs, APs, or client and server computers may also be used to implement the system and method of the present invention.
In an alternative exemplary embodiment of themobile network100, theMCPs20,25 may connect to thecommunications network50 directly via wires despite being portable. For example, rather than real-time reporting, theMCPs20,25 may only be required to connect periodically to themobile network100 for updates on their movements as monitored by theirrespective sensors120. Furthermore, no wireless capabilities orcommunications network50 may be needed entirely. In such a situation, thesensor120 makes measurements to be processed internally for use locally by the users or manufacturers. For example, the measurements may be used to suggest replacing or repairing theMCP20,25 because it has exceeded a threshold of abuse and is in danger of malfunctioning.
FIG. 3 shows anexemplary method300 for monitoring theMCPs20,25. In thestep310, certain distinct characteristics of events (e.g., the second data) are identified and programmed into theMCPs20,25. The second data may include a specific threshold value and/or a threshold range of changes in the directional orientation and motion of theMCPs20,25. The characteristics may include, for example, maximum or minimum threshold values or prerecorded motions. The user (e.g., the manufacturer, a system administrator or any other authorized person) may designate or, if desired, make changes to these characteristics. For instance, theMCPs20,25 may be prepackaged by the manufacturer with static abuse maximum values that are inaccessible or not editable by the user. Alternatively, the threshold may simply be dynamic default values adjustable to future specifications.
In thestep320, theMCP20,25 is continuously monitored by thesensor120 for changes in the directional orientation and/or motion/movements that may, constitute the occurrence of a predefined event. An event may include, for example, theMCP20,25 being dropped, jerked, tugged, shaken a certain number of times within a certain time period, or remaining still for a specified duration. Whenever theMCP20,25 experiences detectable motion or an extended lack thereof, the first data is generated. Thesensor120 may make no effort to differentiate between or prioritize directional orientation or motion values, returning all results to theprocessor110 for processing.
In thestep330, theprocessor110 compares the measured first data with the predetermined second data. If the characteristics of the first data match those of the second data, theprocessor110 determines that an event has occurred and a corresponding predetermined procedure needs to be selected. At the occurrence of an event, theprocessor110 may also attach to the first data at least one of a time/date of each event, a status of the computing arrangement, a direction of the acceleration, and environmental data. In an alternative exemplary embodiment of the present invention, the above-described attachment may occur as a part of the predetermined procedure.
For example, when thesensor120 detects that theMCP20,25 came to an abrupt stop after being accelerated for a short period of time, theprocessor110, after comparing that information to at least a portion of the preprogrammed second data, may conclude that theMCP20,25 dropped to theground30. From the magnitude and duration of acceleration, theprocessor110 may also determine whether the drop was forcibly induced (e.g., by an abusive user) and the distance h1 or h2 of its displacement. Furthermore, from the direction of impact and other data, theprocessor110 may also approximate the part of theMCP20,25 that initially made contact with theground30 and whether any critical components were directly impacted. Such information may be attached to the first data and may be helpful in determining whether the fall poses a danger to theMCP20,25's continued operation.
Due to practical considerations (e.g., memory limitations and processing power) and because not all event occurrences may be significant, the reporting and recording of all movements of theMCP20,25 no matter how minor, although possible, may in some instances be impractical. Movements within acceptable limits may be superfluous and have no bearing to applications of the present invention. Therefore, in thestep340, the first data is measured against threshold values contained in the second data. The first data is retained only when at least one event and/or reading satisfies the threshold values or matches the prerecorded motions of the second data; otherwise the first data is discarded and themethod300 is returned to thestep320 for the monitoring of new events.
If the first data falls within the threshold of the second data, themethod300 continues to thestep350 where theprocessor110 selects, as a function of the first data, at least one predetermined procedure for execution. In particular, theprocessor110 analyzes the measured first data and determines the corresponding procedure of the plurality of predetermined procedures.
In thestep360, the predetermined procedure is executed. The execution of the predetermined procedure may depend upon the specific application of the present invention. For example, the first data may be stored into thenon-removable memory130 or theremovable memory140. A plurality of stored first data records form an event history of theMCP20,25. The event history may be readily accessible to any user of theMCP20,25, or may be password protected and/or encrypted so that only authorized personnel (e.g., the network administrator or the manufacturer) may gain access.
Other examples of predetermined procedures include encrypting the first data so that it may be accessible only by an authorized user, transmitting the first data to a remote computer, analyzing the event history of theMCP20,25 for service recommendations, reporting the cause of any damages, issuing precautionary warnings of theMCP20,25's condition, changing theMCP20,25's display, powering off, etc. After the predetermined procedure has been successfully executed, themethod300 may resume again at thestep320 to monitor for new event occurrences.
The examples discussed in the foregoing discussion are for illustrative purposes only and are not representative of all possible applications of the present invention. Rather, the present invention may be applied across a diverse range of industries, practice areas, and purposes. The description that follows further outlines the features and advantages of several exemplary applications of the present invention. However, as will be apparent to one skilled in the art, theMCPs20,25 may benefit from and make use of an added motion sensor component according to the present invention in many other ways.
AsMCPs20,25 are increasingly being integrated into the daily operations of businesses today, a need has developed to ensure that theseMCPs20,25 can withstand the rugged treatment to which they are often subjected. Conventional design and construction techniques yieldMCPs20,25 that exhibit levels of performance that are only marginal in terms of reliability and durability under the demands of industrial environments. Damaged or malfunctioningMCPs20,25 may have devastating effects on the numerous businesses currently relying on mobile solutions. For example,MCPs20,25 that are completely inoperable may result in costly delays while replacement products are sought. Also,MCPs20,25 with latent malfunctions may cause undetectable computational errors that corrupt systems and induce further errors down the line.
Typically, the user of theMCP20,25 has no reliable way of anticipating malfunctions and only discovers a problem as it manifests itself. By that time, damage has often already occurred. Therefore, there is a great need for IT and customer service personnel be able to monitor and accurately determine when theMCP20,25 has surpassed an intolerable threshold of abuse. This may be accomplished by establishing measured levels of acceptable and unacceptable usage profiles according to the exemplary embodiments of the present invention. In this way, user profiles may be established and predictions may be made of when theMCP20,25 should be replaced prior to it actually malfunctioning. In instances where theMCP20,25 is being abused, the customer may intercede to minimize the abusive treatment, thereby reducing the amount of service to and/or replacement of theMCP20,25 required and lowering the total cost of ownership.
Referring to theexemplary method300 ofFIG. 3, for example, a maximum level tolerable abuse may be defined in terms of the number of times theMCP20,25 is dropped to theground30. Thus, in thestep310, a minimum height constituting a drop and maximum number of drops may be specified as a second data. TheMCPs20,25 may be configured to only record values exceeding the predefined magnitudes. Accordingly, if a threshold for drop altitude were set somewhere between h1 and h2, theMCP20 dropping to theground30 from the height h1 would not appear in its event history, but theMCP25 dropping to theground30 from the height h2 would. In both cases, thesensor120 generates a first data relating to velocity and acceleration values, and are forwarded to theprocessor110. Theprocessor110, after comparing the first data to the second data, then determines that a drop has occurred and attaches certain other event data. After comparing the first data to the predefined threshold values, the first data is either retained or discarded. Finally, a predetermined procedure is selected based on the first data and executed.
In other exemplary embodiments, theMCPs20,25 may similarly be directed to only retain and execute procedures when the first data indicates some form of an abuse. For example, theMCPs20,25 may be programmed to execute a procedure only after a predetermined number of events occurring within a predetermined time period has been detected. Furthermore, theMCPs20,25 may instead only retain and perform operations when the first data shows an impact to certain critical components or that are oriented in a certain predetermined direction and/or are of a certain predetermined force.
As previously mentioned, the predetermined procedure may vary depending on the specific application of the present invention. For example, in abuse indication, the predetermined procedure may simply be a real-time on-screen display of the updated event history of theMCP20,25. If theMCP20,25 is being exposed to usage profiles beyond its intended use, it may also be desirable to alert the user through visible warning (e.g., on-screen precautionary displays, flashing LEDs), audible sirens (e.g., using a speaker, headset, receiver) or mechanical alerts (e.g., vibrations, pager motors).
Furthermore, usage profiles detrimental to theMCP20,25 may be brought to the attention of a remote party with an interest in its condition. IT and customer service personnel, for example, may monitor theMCP20,25's event history in real-time, on-site or off-site, through the communication links of themobile network100. In instances where real-time monitoring is impossible or impractical, updates may instead be made in periodic or predetermined intervals. For example, theMCP20,25 may have no wireless communication capabilities, may be beyond the wireless operating range of theAP10, or it may be desirable to conserve the limited bandwidth of themobile network110. In such situations, the number and level of unacceptable usage instances experienced by theMCP20,25 may be archived for retrieval at a later time. A periodic servicing and maintenance schedule may be established, during which remote parties may obtain updates. The event history may also be downloaded at the end of a shift when theMCP20,25 is returned to a docking station or charging cradle.
With theMCP20,25's event history, remote parties (e.g., IT and customer service personnel) may perform operations beyond servicing theparticular MCP20,25. This information may be used by manufacturers for research and development for the benefit oflater MCPs20,25. By establishing the usage patterns ofMCPs20,25 operating under similar conditions, future specifications may be tailored to actual conditions of use, adjusting levels of durability based on the expected conditions to which theMCPs20,25 may be subjected. Acceptable standards of motion data may then be refined and monitored for excessive abuse according to a new set of criteria.
Still another advantage of the present invention to manufacturers is the ability to archive and retrieve warranty information. Manufacturers' warranties typically only insure against defects arising from production or out of the normal course of usage of theMCP20,25, neither of which includes theMCP20,25 being dropped in a way that may violate its specifications or being otherwise abused by the customer. However, without any actual knowledge of theMCP20,25's usage, manufacturers presented by a customer with a malfunctioningMCP20,25 often has no method to accurately determine the cause of the malfunction. If usage information is available either within theMCP20,25's memory or in transmissions to the manufacturer, warranty claims may more easily be verified or discredited.
In addition to interacting with the user or remote parties, theMCPs20,25 of the present invention may also autonomously monitor their own condition and take actions accordingly. The probability of losing critical data increases substantially when theMCPs20,25 are used beyond their intended usage profiles or environmental design specifications. The exemplary embodiments of the present invention allow theMCPs20,25 to take preventative measures to ensure against harm during an abusive event. For example, while anMCP20,25 is experiencing excessive motion beyond a predetermined usage threshold value (e.g., as theMCP20,25 is dropping to theground30 from height h1 or h2), theprocessor110 in thestep360 may terminate programs containing critical information to prevent data corruption. Access to thenon-removable memory130 or theremovable memory140 by any other components may also be temporarily disabled, avoiding any possible loss of data. If necessary, theMCP20,25 may power off or switch into standby mode and not be allowed to resume operations until the abusive event has passed or subsided back within an acceptable range.
Although the exemplary applications of the present invention in foregoing description has primarily focused on abuse indication, the present invention may also be used in a variety of other settings. As described below, these settings include, for example, power management, gesture input, compensating for undesired motion, display orientation, and security.
The power management properties of MCPs have always been a primary focus of product design engineers. Due to their limited size and weight and their mobile nature, MCPs usually have limited power supplies (e.g., rechargeable or disposable battery packs). Developing MCPs that operate for long periods of time, without sacrificing mobility, is an ongoing design challenge. Designing a robust power management system that optimizes and conserves power is a critical element in addressing this challenge.
Understanding theMCP20,25 directional orientation with respect to the user is possible by incorporating the previously describedsensor120. As such, it is possible to enhance current power management systems by turning on and off various systems when appropriate. For example,many MCPs20,25 have a display and backlight that use a large amount of the available power supply. Utilizing the orientation aspect of the sensor may enable theMCP20,25 to keep the display and backlight on only when the display is within the user's viewing angle and range. By employing the exemplary system and method of the present invention, when theMCP20,25 is rotated past the viewing angle or brought beyond the visible distance for a predetermined time period, the display and backlight may shut off to save power. When theMCP20,25 is rotated back within user's viewing angle or brought within the visible range, the display and backlight may instantaneously turn back on.
Another way in which the present invention may optimize the power management of theMCP20,25 may be by switching it into a power conservative state when not in use. Conventional power management systems typically shut down theMCP20,25 or switch it into idle mode after a preset amount of time transpires with no interaction from the user. The preset time period is usually adjustable by theMCP20,25 software. The present invention uses the lack of motion as an additional trigger to switch theMCP20,25 into the idle or shut down modes, thus taking advantage of tendency of theMCPs20,25 to be in motion when in use, and conserving energy when at rest. The amount of motionless time needed to trigger the power saving state may also be adjustable by theMCP20,25 software.
Continuing with some exemplary applications of the present invention, the combined sensor andMCP20,25 of the present invention may also simplify theMCP20,25's operation through a gesture input. The advantages afforded by increasingly advanced computing products are often offset by sacrifices to usability and user-friendliness. Elaborate menus, onscreen buttons, procedures or the like frequently frustrate users and impede rather than advance productivity. The ability to sense and analyze motion through the present invention enables theMCP20,25 to recognize and react to various motions or user gestures. These motions or gestures may be pre-established to trigger theMCP20,25 to perform various functions that would otherwise need to be actuated manually.
For example, if theMCP20,25 equipped with a display is in document viewing mode and orientation, a quick flip of the user's wrist detected by thesensor120 may coincide with the software application flipping to the next page of the document. In another example, when long lists of application options are being displayed to the user, a wrist roll gesture could trigger theMCP20,25 to start scrolling down the list. In still another example, if theMCP20,25 is a device with data capturing capabilities (e.g., an imager, scanner, camera), a motion detected corresponding to a certain pre-recorded gesture may trigger theMCP20,25 to turn on the data capture functionality.
Still another advantage of the present invention is the ability to compensate for an undesirable motion. Although not as detrimental to theMCPs20,25 as motion constituting abuse, minor motion values may still adversely affect applications that require as little motion as possible. For example,MCPs20,25 with data capture capabilities utilizing various camera technologies produce blurred or out of focus pictures when in motion. Various methods have been developed attempting to offset such undesirable effects, such as weights or stands that minimizes or cancels out extraneous motion.
The present invention may be utilized to address this problem without the need for cumbersome physical attachments or mechanical devices. Undesirable motion may be recognized, processed, and de-sensitized through various software applications employed by theMCP20,25 under the exemplary embodiments of the present invention. TheMCP20,25 may identify a non-acceptable operating situation to the user due to motion through the display or other alert mechanisms, and/or automatically have the software compensate for the motion during the data capture event.
Furthermore, inMCPs20,25 equipped with displays, the orientation sensing capability of the present invention may also conveniently adjust the display orientation with respect to the user.MCPs20,25 typically format display data in landscape or portrait mode. Newer mobile software applications enable the display data format to be manually switched between the two. The present invention allows the orientation of theMCP20,25 to be monitored relative to the user, enabling theMCP20,25 to automatically switch the display data format between the landscape and portrait modes.
As a final exemplary application of the present invention, the combined sensor andMCP20,25 of the present invention may be used for purposes of security. Because theMCPs20,25 are portable, they are easily misplaced or stolen. By employing the exemplary system and method of the present invention, theMCPs20,25 may be able to incorporate security features that indicate their location to the user or prevent use by unauthorized personnel. For example, when theMCP20,25 is at rest for a preset period of time (e.g., during recharge, overnight storage), it may enter a secure mode and be programmed to trigger an alarm when motion to theMCP20,25 is detected. This alarm may be local to theMCP20,25, using audible, visual, or mechanical features. At the same time or as an alternative, the alarm may be triggered in a remote device on-site or off-site using the previously described communication systems. If theMCP20,25 utilized tracking technologies (e.g., global positioning system), it may also convey its location. The security features may additionally lock terminal applications, preventing theMCP20,25 from being used until an authorized user password is entered.
The present invention has been described with the reference to the above exemplary embodiments. One skilled in the art would understand that the present invention may also be successfully implemented if modified. Accordingly, various modifications and changes may be made to the embodiments without departing from the broadest spirit and scope of the present invention as set forth in the claims that follow. The specification and drawings, accordingly, should be regarded in an illustrative rather than restrictive sense.