Not Applicable.
Not Applicable.
The invention disclosed broadly relates to the field of information processing systems and more particularly relates to the field of portable personal computing devices.
As computers have become among the most important tools in the current business environment, many users rely on multiple computing devices to perform varied tasks. Some of the current problems that chief information officers and users face include: 1) multiplication of the costs of managing machines (virus protection, security patches, application upgrades); 2) cost of multiple operating system and application licenses; 3) creating disk backups; 4) maintaining machine and disk passwords; 5) difficulty of restoring machines after disk crashes; 6) securing against network attacks; and 7) user data being scattered across a collection of machines. There have been several attempts to address these concerns. Users are primarily concerned with access to information relating to the tasks that they were performing using their computers. Since some of these tasks are long running, users desire the ability to suspend partially completed tasks and resume working on these tasks at a later point in time. For instance, a user may start editing a document at the office, and would like to continue working on the document at home, or the next day at a different location. Currently laptop computers help address this requirement. Users routinely suspend their laptops and resume them later. The suspend-resume cycle preserves the computation state on the user's laptop, enabling users to quickly suspend their tasks and resume them later.
However, laptop computers come with a set of disadvantages. Laptop computers are relatively large and heavy because they contain everything: CPU, memory, disk storage, as well as the screen, keyboard and pointing device. Laptops also do not operate for a very long duration of time when powered solely by internal batteries.
Given the widespread availability of computers and peripherals such as keyboards, pointing devices, monitors, and the like, it may not be necessary for a user to carry all of these items in the form of a laptop computer.
It would be advantageous to devise a scheme where a user can take advantage of a widely-deployed installed base of personal computers, to suspend and resume their tasks at different locations while carrying something that is much smaller, lighter and less onerous to maintain than a laptop computer.
The key to suspending and resuming tasks is to find a way by which a user's personal computing environment can be moved from one location to another. A user's personal computing environment consists of the instantaneous state of the applications the user is working on, the configuration of the applications, the operating system on which the applications run and the configuration of the operating system. It is all the more important to be able to move a user's personal computing environment from one place to another in a manner that takes advantage of the widely deployed personal computing infrastructure, in a manner that uses existing systems without trying to force them to change or attempting to replace them with other systems.
We first consider existing approaches that attempt to transport a user's personal computing environment along with the user. The IBM Meta Pad is a portable device comprising a CPU, memory, disk, a suspend battery, and a docking connector which connects to a docking station which in turn connects to a mouse, keyboard and screen. Users work on their tasks using the Meta Pad and suspend it like they would suspend a laptop and eject the Meta Pad from its dock. The suspend battery maintains the state in the Meta Pad. The Meta Pad eliminates the need to carry the screen, keyboard and the pointing device. An inconvenience of this approach is that a proprietary Meta Pad docking station is needed at each location where the user needs access and it effectively attempts to dislodge the existing installed base of personal computers.
The Intel Personal server is a device comprising a CPU, memory, disk and Bluetooth or IEEE 802.11 network interface. Such a device can communicate with a standard personal computer, but the main problem with this approach is the use of wireless connections for exchanging all data between the personal computer and Intel Personal Server. Every communication requires HTTP server/SOAP connections from an environment to a belt worn server. While this concept has some merit, it requires the environmental personal computer to support standard interfaces as well as applications to deal with the data that is carried on the personal server. The environmental personal computers still need to be administered and managed, and the battery life of the personal server is a serious usability problem. The Intel Personal Server does not enable the user to carry their personal computing environment with them. It only enables them to access some information that is on their Personal Server device at different locations.
Currently Linux operating system distributions exist that contain an entire operating system and applications on a bootable CD/DVD (compact disk/digital video disk) or other read-only media. Users can boot any PC (personal computer) from the CD and create a familiar desktop environment on it. Further they may carry read/write USB (Universal Serial Bus) flash storage with their personal files. In this approach the user's computation state is not preserved as the user moves from one machine to another. Further, the user needs to carry two items, the bootable read-only CD and a R/W storage device for data that is modifiable.
The diskless Sun Java Station/IBM Network computer attempted to solve some of the above problems by using a thin client connected to a fat server by fat pipes. This approach has the drawback that it relies heavily on a browser, the Java OS and Java applications. Slow connectivity, especially from remote locations, remained an issue with such an approach. The approach also took away the personalization aspect by disallowing the user to install any applications. In addition, this approach tried to dislodge and replace the existing personal computer ecosystem.
Internet Suspend/Resume (ISR) from Intel is a technology for transporting personal computing environments over a network. It relies on suspending and resuming the state of a virtual machine; it stores the suspended state on a distributed file system, from where it can later be retrieved and resumed. An important limitation of the ISR approach is that it requires-network connectivity. It would be advantageous to do away with the need for any network connectivity by exploiting portable storage devices. Another limitation of ISR is that it requires that end systems be pre-configured with ISR software. It would be advantageous to have a system that does not require any software to be pre-installed on end systems.
The Microsoft Remote Desktop provides a solution that just sends the key strokes and events to the host (server) computer. The host computer then sends the graphics over to the remote (client) computer. This is similar to what X11 did for workstations in the 80s and 90s. The session is not resumed where it was left off. This is just a client server approach.
Xmove is another approach (see Ethan Solomita, James Kempf, and Dan Duchamp, “XMove: A Pseudoserver for X Window Movement,” The X Resource, (1):11, pp. 143-170, July 1994) This allows an X window on the remote machine to be moved to another remote machine. The application continues to run on the same server machine. This is done by capturing the state for that particular X Window by introducing a pseudo server in the middle.
There have been a few implementations of window movement using the toolkit approach. Trestle is a toolkit that can move shell windows from one display to another. XTk is a window toolkit that allows window widgets to move from one server to another. XTk introduces an additional step in widget creation: screen binding. Screen binding binds a widget to a screen without geometrical layout. This allows the widget's geometry negotiation to account for screen geometry should it be moved. An additional step is also introduced in widget shutdown, to maintain widget structures in case they should be moved to another screen.
In the virtual network computing (VNC) system, server machines supply not only applications and data but also an entire desktop environment that can be accessed from any Internet-connected machine using a simple software NC. Whenever and wherever a VNC desktop is accessed, its state and configuration (right down to the position of the cursor) are exactly the same as when it was last accessed. The technology underlying VNC is a simple remote display protocol. Unlike other remote display protocols such as the X Window System and Citrix's ICA, the VNC protocol is totally independent of operating system, windowing system, and applications The VNC system is freely available for download from the ORL Web site at http://www.orl.co.uk/vnc/. It does not require the user to carry any hardware. However, it assumes network connectivity. See T. Richardson, Q. Stafford-Fraser, K. R. Wood, and A. Hopper, “Virtual Network Computing”, IEEE Internet Computing, Vol. 2 No. 1, January/February 1998 pp 33-38.
Although the foregoing solutions all have their own merits, there is a need for a truly portable solution that can provide a user with his or her work environment in any host environmental computer regardless of its configuration or location.
The above problems or shortcomings in portable computing environments are solved by using a portable personal computing environment server according to the invention. The portable personal computing environment server can be used in most host computer systems (e.g., PC-compatibles) regardless of their configurations. The portable personal computing environment server comprises the user's most recent computing state for restoration in the host system.
We solve the problems discussed above with an attachable storage device 100 (hereafter called a portable personal computing environment server or portable server) that can be connected to any host personal computer. Referring to
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Storage of all of the above software and data will require ten or more gigabytes of storage depending on how much of the computing environment and state the user wishes to capture in the storage device. The storage device 104 is preferably non-volatile so that a battery is not required. Even in embodiment 200, the storage device 202 is preferably non-volatile so that the battery or other power supply is not required when the personal computing environment server is not actively being used. Storage device 104 or 202 could be a hard disk drive, non-volatile semiconductor storage such as FLASH memory, a magnetic random access memory, optical storage or other suitable device.
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When the user wishes to resume work at another host, he or she connects the portable server to the second host and commences a resume operation. FIGS. 8A-C show such a resume operation. First, in
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In step 908 the host system retrieves a first stage operating system (OS) and boots into the first stage OS based on the host system configuration. In step 910 a virtual machine environment is created on top of the first stage OS that exports a standard virtual machine interface to the host system. In step 912 the host system retrieves the suspended state corresponding to OS-B and user applications running on OS-B. In step 914 the host system restore the user's computing environment in the host system. Finally, in step 916 the host system provides additional data and applications from OS-B as required by user. The host system also provides data and applications from OS-A as required by the Virtual Machine layer. In embodiment 200, the CPU 208 is used to recognize such requests and service them. Other network packets that are directed to external network sites are simply forwarded to Ethernet interface 208. It discovers the host OS configuration at boot time and sets itself up to handle the configuration. Moreover, the second level OS may not be suspended; it may also boot.
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As mentioned above, not all BIOS versions can boot from a USB device. For a system with such a BIOS, a user may create a diskette with a USB/Firewire driver. The first stage bootloader from the diskette and the rest of the boot process commences from the USB/Firewire disk.
Instead of using a wired Ethernet connection it is also possible to use a wireless local area network (LAN) connection according to IEEE standard 802.11.
A system as discussed above can change the entire computing paradigm. Consider the case of a hospital where electronic access to patient records is becoming more and more common. Each of the doctors can use a device according to the invention to carry his or her own portable personal computing environment server and connect it to different personal computers in the hospital (for example, in the radiology department, a central nursing station, etc.) and be able to securely access patient data. In another example, a knowledge worker could carry his portable personal computing environment server home, do some work at home and bring it back to work the next morning and connect to his office personal computer and resume where he left off without worry about synchronizing his data. The savings to the user could be significant. Over time, if some of the user's personal computers become diskless because they only operate in concert with his portable personal computing environment server, then all of the problems such as OS licenses, upgrades, security patches, backups, and the like go away.
Therefore, while there has been described what are presently considered to be the preferred embodiments, it will be understood by those skilled in the art that other modifications can be made within the spirit of the invention.
This is a continuation of U.S. patent application Ser. No. 10/795,153, which is herein incorporated by reference.
Number | Date | Country | |
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Parent | 10795153 | Mar 2004 | US |
Child | 11154084 | Jun 2005 | US |