JPH10506208A - Micro personal digital assistant - Google Patents

Abstract

(57) [Summary] A personal digital assistant module (10) having a local CPU (11), a memory (13) and an I / O interface (16) is connected to a bus (26) connected to the local CPU (11). , Including a connector on the surface of the personal digital assistant (10), and having a host interface (29) for interfacing with the bus connector of the host general-purpose computer (66); and a personal digital assistant (10) and a host general-purpose computer (66). Performs direct bus communication between In one embodiment, the personal digital assistant (10) also has means for storing a security code. The personal digital assistant (10) according to the present invention provides a docking protocol for connecting to the memory (13) of the personal digital assistant (10) based on one or more passwords given to the host computer (66) by the user at the time of connection. A host / satellite combination is formed with the host computer (66) having a docking bay controlled by the host computer (66). In another embodiment, the personal digital assistant (10) also has an expansion port (20) connected to the local CPU (11), and expansion peripherals may be connected and operated by this expansion port (20). .

Description

Description: FIELD OF THE INVENTION The present invention relates to the field of portable computers, and in particular to a small portable computing device technically known as a personal digital assistant. This application is a continuation-in-part of the applicant's other applications S / N 08 / 144,231 and S / N 08 / 031,805. BACKGROUND OF THE INVENTION At the time of writing this application, personal digital assistant (PDA) devices occupy a promising position in the computer market. In this manner, a relatively inexpensive, small, portable computing device with software specifically written for tasks that a user may perform while traveling is very effective, and therefore marketable. There is also the idea of offering a computer product. Hewlett-Packard's Apple Computer and other well-known computer vendors are investing in such systems at a modest risk. When new systems are introduced and they become popular, there are still a number of shortcomings and problems with what is currently known about them. For example: Installed PDA systems are relatively expensive, with starting prices ranging from hundreds of dollars to more than $ 2,000. Consumers are not very responsive because they are competing for distribution prices for desktop systems at such a price. It is true that prices will fall with increasing production and competition, but high-end starts are also rejected by potential users. 2. The provided system is still relatively large considering the limited range of tasks to be accomplished. Most are certainly too large to be conveniently carried in a breast pocket. Newton manufactured by Apple Inc. weighs about one pound and is approximately the size of a VHS video cassette. 3. A major drawback of the provided PDA systems is the way they transfer data between the user's desktop device or another host and the PDA. Known communications are performed by modem, infrared communication and serial connection. These all require user intervention, modulation at one or both ends of the channel, etc., which are time consuming, error prone, and large in hardware (expensive). Currently, Newton offers the option of modem and / or LED communications to increase overall costs. 4. In known PDAs, software is typically stored in ROM, making updating applications difficult and sometimes impossible. This is problematic because the PDA user does not want the PDA to always have the same capabilities. Typical users are those who travel and work while they are traveling. These users need different features, for example for traveling to Taiwan rather than to France. A quick and convenient means of updating and replacing software is needed. 5. Another problem is that the data files that the user manipulates while traveling are typically located in a home unit, here called the host device, such as a desktop device or notebook or other portable computer in the user's office. It is a file. Having two or more sets of important data with differences that must be corrected in a timely manner is very cumbersome. This is likely to cause endless struggle if the files are not updated correctly. At best, current PDAs must use a relatively slow compressed bus to download and upgrade files. Typically, this is done by a serial port using a concatenated application such as Laplink. What is needed is a small and inexpensive PDA that has a series of features that eliminate the risks and problems described above. This new device needs to be approximately credit card sized and smaller than those currently being implemented, presumably modeled in the form factor of the PCMCIA Type II or Type III standard. At least the smallest version must be produced cheap enough so that it can be sold in the range of nearly $ 100 to $ 200, making it a device that is considered a relatively inexpensive necessity. This type of PDA device is the subject of the present invention and is referred to by the inventor as a micro PDA or μPDA. A very important feature of a μPDA in the context of the present invention is a direct parallel bus interface with a connector that allows the device to be connected by inserting the device into a docking bay in a host device. . In addition, there is a need for a means for effectively disabling the CPU in the µPDA when the µPDA is coupled into the host and allowing direct access to both the µPDA software and data storage by the host CPU. This direct access provides the immediate ability to communicate in the fastest way available between the µPDA and the host, and also facilitates the additional important features described below. The μPDA also needs to have an optional compressed bus interface including a connector remote from the host interface, and additional devices such as fax modems, cellular communication devices, printers, etc. may be used. An additional feature that can optionally be provided in another aspect of the invention is an interface at the host that allows the user to select a pre-arranged mix of software to load into the µPDA. is there. This feature allows the user to quickly select the data to be loaded on the application and possibly also on the µPDA satellite, and to configure a smaller and more portable device for a specific itinerary and purpose. Includes a set of control routines that operate with the display and input means of the host. Another desirable feature is the ability to automatically update data files. In this aspect of the invention, with the µPDA connected, the data on the host is automatically updated on the µPDA if a date and / or time stamp after the data on the µPDA is transmitted. And vice versa. Returning to the original situation from use of the μPDA, when the host connects to the satellite, the host accesses, determines the location of the latest file, and updates. This feature requires having some built-in user prompting to be most effective. That makes μPDA a true satellite system. SUMMARY OF THE INVENTION In a preferred embodiment of the present invention, an enclosure for housing and supporting internal elements, a microcontroller in the enclosure for performing digital operations to manage the functions of the personal digital assistant module, and a memory bus structure. A personal digital assistant module is provided that is connected to the microcontroller and includes memory means for storing data and executable routines. Within the enclosure, power supply means for supplying power to the functional elements of the personal digital assistant module, display means operable by the microcontroller and configured on the surface of the enclosure, and connection to the microcontroller And input means for providing instructions and data to the personal digital assistant module. Host interface means, including a host interface bus structure, which may be configured as a PCMCIA bus interface, is connected to the microcontroller and the first portion of the host interface connector at the surface of the enclosure, the host interface means comprising a host interface means. The microcontroller is configured to connect directly to a computer compatible bus structure. In one embodiment, a personal digital assistant module has an expansion bus interface that includes a microcontroller and an expansion bus structure connected to a first portion of an expansion bus connector that connects the microcontroller to peripheral devices. . Various peripherals are provided for use with the personal digital assistant module of the present invention. In yet another aspect, the personal digital assistant module is also connected to the microcontroller and includes an EEPROM including one or more codes specific to the personal digital assistant for uniquely indicating the personal digital assistant to the digital device connected by the host interface. And a non-volatile storage device as described above. In a preferred embodiment, the display and input means for the personal digital assistant are configured as a touch screen and LCD display located on the surface of the outer case of the personal digital assistant. In one embodiment, a pointer device configured as a thumbwheel and in another embodiment as a pressure sensitive pad is provided as part of the input capability. The personal digital assistant module forms a unique combination with a general purpose computer host having a personal digital assistant as a satellite device. The host in this example has a coupling bay specially configured to connect the personal digital assistant and form a direct bus connection between the personal digital assistant's local CPU and the host CPU. The main device (host) may be a small portable computer such as a desktop device, a notebook computer, or a handheld computer. This combination does not provide power and convenience before use. In accordance with various aspects of the present invention, there are also provided many other digital devices such as modems, scanners, data acquisition peripherals, cellular phones and software vending devices, all of which may be extended bus interfaces, or often host An interface may be added to the personal digital assistant. A personal digital assistant provided according to an embodiment of the present invention is a more compact device than a normal PDA. It represents a new dimension in computer applications and adaptability, is a form that can be used very conveniently by almost everyone, is expected to be effective for almost everyone, and is easy to sell It is. It solves the communication problems inherent in personal digital assistants associated with large, powerful computers with a very inexpensive device that fits in the user's breast pocket. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a perspective view of a μPDA according to an embodiment of the present invention. FIG. 1B is a plan view of the μPDA of FIG. 1A. FIG. 2 is a cross-sectional view of the μPDAs of FIGS. 1A and 1B. FIG. 3 is a block diagram of the μPDA of FIG. 1A and peripheral elements. FIG. 4 is a more detailed plan view of the μPDA of FIG. 1A, specifically illustrating an LCD display and a touch screen user interface in aspects of the invention. FIG. 5 is a perspective view of the μPDA and the main notebook computer in an embodiment of the present invention showing the μPDA being about to be connected into the connection bay of the notebook computer. FIG. 6 is a block diagram of a μPDA connected in a connection bay of a host computer according to an embodiment of the present invention. FIG. 7 shows a logical flowchart of the steps for connecting a μPDA in a host computer according to an embodiment of the present invention. FIG. 8 is a perspective view of a μPDA software vending apparatus according to an embodiment of the present invention. FIG. 9 is a perspective view of a μPDA enhanced user interface according to one embodiment of the present invention. FIG. 10 is a top view of a μPDA having a microphone according to an embodiment of the present invention. FIG. 11 is a perspective view of a μPDA coupled in a dedicated cellular or cordless telephone according to one embodiment of the present invention. FIG. 12 is a plan view of a μPDA having a speaker and a pager interface according to one embodiment of the present invention. FIG. 13 is a plan view of a μPDA having an infrared communication interface according to an embodiment of the present invention. FIG. 14 is a plan view of a μPDA having a scanner accessory according to one embodiment of the present invention. FIG. 15 is a plan view of a μPDA with a fax modem installed according to one embodiment of the present invention. FIG. 16 is a plan view of a μPDA having a printer adapter interface according to one embodiment of the present invention. FIG. 17 is a perspective view of a μPDA coupled to a barcode reader having a data collection peripheral according to one embodiment of the present invention. FIG. 18 is a perspective view of a μPDA having a solar cell charger according to one embodiment of the present invention. FIG. 19 is a plan view of four μPDAs interfaced to a dedicated network console for intra-PDA communication according to one embodiment of the present invention. FIG. 20 is a perspective view of a μPDA according to the present invention connected to a standard sized keyboard by an expansion port. FIG. 21A is a plan view of a flexible retractable keyboard according to the present invention. FIG. 21B is a side view of FIG. 21A. FIG. 21C shows the flexible keyboard of FIG. 21A wrapped around a compact cylinder and secured with a belt. FIG. 22 is a perspective view of a single key cell in a flexible keyboard according to one embodiment of FIGS. 21A and 21B. FIG. 23A is a cross-sectional view of the key cell of FIG. 22 taken along line 23A-23A of FIG. FIG. 23B is a plan view of the lower layer of the key cell of FIG. 23A as viewed in the direction of arrow 29. FIG. 24A is a plan view of the lower layer at the position of the shift key. FIG. 24B is a plan view of the upper layer as viewed from the same viewpoint as FIG. 24A. FIG. 25A is an end perspective view of a flexible keyboard containing a control circuit, with layers separated to show details inside. FIG. 25B shows the control circuit module viewed from an angle of about 90 ° from FIG. 25A. FIG. 25C is a diagram of the control module in the direction of arrow 75 to show the structure of the contact pads associated with the module. FIG. 25D is a cross-sectional view taken along line 25D-25D of FIG. 25A where the two layers are joined. FIG. 26A shows another embodiment that communicates with a properly installed computer without cables. FIG. 26B shows another embodiment in which the wiring matrix is connected directly to the computer through connection cables. FIG. 27A shows a flexible keyboard of the present invention connected to a computer by a transmission cable. FIG. 27B illustrates a flexible keyboard according to one embodiment of the present invention in which the code is transmitted by a magnetic field. FIG. 28 is a perspective view of a computer having a keyboard according to the present invention. FIG. 29 shows a keyswitch matrix interfaced to a microprocessor and magnetic transmitter according to the present invention. FIG. 30 shows a receiver and demodulation circuit that receives a magnetically encoded scan code and reconstructs the associated digital scan code therefrom. FIG. 31A is an exemplary diagram of an electromotive force in a reception loop according to an embodiment of the present invention. FIG. 31B is a serial digital scan code reconstructed from the magnetically coded code of FIG. 31A. Description of the preferred embodiment FIG. 1A is a perspective view of a μPDA 10 according to one embodiment of the present invention. In this embodiment, the device is designed with a PCMCIA standard type II factor having a height D1 of about 5 mm. The body 12 is described in further detail below, where the female portion 14 of the connector mates with the mating male portion of the connector at the host computer and one end for connecting the μPDA internal circuitry directly to the body internal bus. The portion has a concave portion. The main unit may be a notebook computer having a connection bay for a μPDA. Coupling bays are also included in desktop and other types of computers, and other types of digital devices, some examples of which are described below. Still referring to FIG. 1A, in this embodiment there is a combined I / O interface 16 formed on one side of the μPDA, and soft key operation in cooperation with an interactive control routine operable with the μPDA in an independent mode. A display device superimposed on a touch-sensitive planar structure. Although not shown in FIG. 1A, the host computer device may be configured to be guided along the case side of the device to guide the module into and out of the coupling bay. Further, they may have one or more mechanical features that facilitate coupling and separation of the modules in the coupling bay. FIG. 1B is a top view of the μPDA of FIG. 1A, showing that the thumbwheel 18 is formed at one corner of the μPDA. The thumbwheel in this embodiment is an input device capable of inputting with amplitude and directional characteristics, and in some cases, velocity characteristics. The thumbwheel has many uses in cooperation with the μPDA and I / O interface 16. One such use is to control the scrolling of images, text, menus, and the like on the display of the device. The thumbwheel performs many of the functions of the pointer device. In this embodiment of the μPDA, a second external connector portion 20 is provided. This connector part is for coupling with a peripheral device as a part of the expansion bus interface. FIG. 2 is a simplified cross-sectional view of the means for constructing a μPDA of the present invention in a Type II PCMCIA or other relatively small package. The IC 34 is contained within a conformable material 36, and the interconnections are achieved by traces on a flexible polymer film 32 shown with the contained structures superimposed. In this configuration, the IC is not packaged in the usual manner with solder leads for assembly on a printed circuit board. Rather, a direct connection is made between the solder pads on the chip and the traces on the Kapton film. Further, the IC indicated by reference numeral 34 is not intended to relate to a particular functioning IC in a μPDA. This sectional view merely shows the method of construction. In this compact structure, traces may be present on the film 32 opposite the interconnect for the CPU and memory for connection to other elements such as the display 25 and touch-sensitive screen 27. The LCD display 25 is formed on one side of the μPDA, and the touch-sensitive interface 27 is provided so as to overlap at least a part of the LCD display. A metal case 38, or other suitable material or combination of materials, surrounds the internal components and is formed consistent with a Type II PCMCIA factor. This simple cross-section shows some structural principles that can inexpensively adapt the required components to the required small factors. In another embodiment, the µPDA is a type III (having a thickness of 10 mm) PCMCIA device using a relatively common technique, such as PCB technology, rather than the contained structure described above. Consists of a forming factor. Various other structures, formation factors, and combination structures are also possible. FIG. 3 is a simplified electrical block diagram of the μPDAs of FIGS. 1A, 1B, and 2. When the μPDA is in stand-alone mode, ie, not coupled to the main unit, the unique microcontroller 11 operates as the CPU of the μPDA. When the μPDA is coupled to the host computer, the microcontroller 11 operates as a subordinate controller and permits bus control to the CPU of the main unit. In the coupled mode, the CPU of the main unit gains control of the contents of the memory of the μPDA and performs the secret security processing procedure described below in many cases. Thus, the host computer can transfer data and software to and from the associated μPDA memory. In other embodiments, many other cooperating modes of operation are achievable between the two CPUs and the accessible memory device. In this embodiment, memory 13 is preferably a 1-2 megabyte non-volatile device, and both control routines for applications and data files are stored in this memory. The memory 13 is a flash memory, a CMOS ROM, a CMOS RAM having a battery, or a combination thereof. The software is stored in the ROM, and the data is stored in the flash memory. The memory device is interfaced to the microcontroller 11 via a dedicated bus structure 17, and the microprocessor 11 is configured to drive the memory bus 17. Battery 15 is the power source in stand-alone mode and can be recharged in one or more of several ways. The power wiring is not shown in FIG. 3, but extends to all of the power units in the μPDA module. When the device is connected into the host, the body power can be connected to the pins via the body interface to recharge the battery. Alternatively, ancillary means, such as solar cells, can be configured to charge the battery and / or supply power to the μPDA. Power solar cells are described elsewhere herein. Further, the battery can be easily removed for periodic replacement. The main body bus connector 14 is a part of the main body interface including the bus structure 26 for connecting to the main body in the connection mode as described above. In a preferred embodiment, the body interface can communicate in either the PCMCIA mode or a mode similar to the PCI mode, PCMCIA Type II, Rev. Follows three criteria. The PCI mode is called the High Speed Intermediate Bus Protocol developed by Intel Corporation and is expected to become the standard bus structure and protocol within the industry. In this embodiment, the physical interface in the body is a slotted bay, which is a typical known bay for PCMCIA devices. The connecting bay is configured as a connecting box and may be a built-in device such as a floppy drive, or it may be other forms. The connector part 20 is a part of the expansion bus interface described above, and has a dedicated bus structure 40 connected to the microcontroller 11. This interface can be configured in many different ways. The purpose of the optional expansion bus structure is to connect to optional peripherals such as printers, fax modems, main body cellular phones, and the like. The expansion bus interface is not an important feature in the minimum embodiment of the present invention, but has significantly improved functionality in many embodiments. The extension interface can take one of several forms. A preferred form is an extended and improved parallel port and protocol based on the invention by the inventor disclosed in the co-pending patent application. Another form is an indexed I / O port with 8-bit address and 8-bit data capability. The requirement for an expansion port is that the connection and communication protocol be compatible with telephone device modems, fax modems, and similar expansion devices. Many other structures are possible. Optional devices, such as the devices described in box 19, can be connected to the μPDA via an expansion bus. A selection of such devices is incorporated into the μPDA in various embodiments to provide various application functions. In the above case, the connection is made through the path 21 and the expansion bus interface via the connector part 20. In the embedded case, the connection is made in the μPDA interconnect trace as shown by path 23. An I / O interface 16 (see also FIG. 1B) is for viewing application related data of the μPDA and for touch sensitive input via soft keys. By softkey is meant by software the assignment of various functions that function as input keys to a particular touch-sensitive screen area. Labels on the I / O interface 16 identify the function of the touch-sensitive area in various operating modes according to the installed machine control routine. The LDC display 25 and the touch sensitive area 27 together form the combined I / O interface 16 described above. In some embodiments of the present invention, data and program protection is provided by providing an electrically erasable program read only memory (EEPROM) 31 connected by a dedicated communication line to the microcontroller 11. The EEPR OM 31 holds one or more codes that are installed when manufacturing is attempted to protect the security of information transfer between the main body and the μPDA. The purpose is to control access to the memory contents of the μPDAs by the body so that each μPDA can be individually configured. To accomplish this, the coupling and bus mastering device control routines are triggered upon coupling, and this protection process is described in further detail below. In other embodiments, the protection code may be provided by a read-only memory (ROM) chip or other permanent or semi-permanent memory source. FIG. 4 is a plan view of a μPDA similar to FIG. 1B, specifically showing an I / O interface. The size and location of the I / O interface 16 can vary, but generally occupy one major portion of the side of the module. In one preferred embodiment, the I / O interface 16 comprises an LCD display having a resolution of 256 x 144 pixels in a screen size displaying 32 by 12 characters. In this embodiment, each character is displayed within the area with a width of 8 pixels and a height of 12 pixels. In another embodiment, the pixel resolution is 320 × 200, corresponding to 40 × 16 characters. The touch-sensitive area of the touch-sensitive screen corresponds to the character area of the display device. By touching the area with a finger or stylus, data can be entered very quickly and with minimal CPU requirements. At one corner, the thumbwheel 18 includes interactive means for controlling the configuration of the display in accordance with installed control routines. Menu 70 is configured to display the current status of the application being processed on one side and provide appropriate user menu options. In a preferred embodiment, input from thumbwheel 18 is used to scroll through menu 70, and the active area can be indicated by a cursor. The user makes a menu selection by pressing the appropriate touch sensitive area. Certain inputs are made to display a menu area on either side of the display device according to user preferences. In this embodiment, certain characters are displayed in area 74, and each character is associated with a touch-sensitive input area. Since the selectable character-only area 70 is too small to display all characters on a standard keyboard, input from thumbwheel 18 will cause the user to pan area 74 where all virtual standard keyboards are displayed. Enable. Movement of the thumbwheel 18 in one direction pans the character area horizontally, and movement in the other direction pans the character area vertically. When the end is reached, the window pans on the virtual keyboard from the other end. In this way, the user quickly pans the character window to display the full standard keyboard and makes a selection with his finger or stylus. Of course, the virtual keyboard is not required to be arranged for access in a standard keyboard format. Characters and punctuation marks are easily displayed in a single strip along the area of the display and can be scrolled by a thumbwheel or other pointer input device. In this embodiment, if the thumbwheel is rotated quickly to avoid the delay caused by panning, the character window will jump rather than scroll to increase the speed of the interface. Further, while a single font is preferred to minimize memory requirements, menu 70 can optionally provide a character display with different fonts and dimensions. It will be apparent to those skilled in the art that there are many alternative forms of character selection and display and there are many ways in which the thumbwheel 18 can be configured to allow scrolling and panning. In this embodiment, the document window 72 is provided above or below the I / O interface 16. The cursor causes the activity location in the document to be placed for editing. Menu 70 provides a selection of valid fonts and input by thumbwheel 18 controls cursor movement on the document. Because the document is much larger in almost all cases than the display capabilities of area 72, it is necessary to pan the document window in essentially the same way as the keyboard window is panned. For example, rotating the thumbwheel 18 in one direction can display a horizontal strip of a document, while rotating the thumbwheel in the opposite direction moves a vertical strip of the same document window. . Soft keys or optional hard keys can be configured to switch between the document and the keyboard window, and the same or different keys can be switched when scrolling the document or keyboard left or right, up or down. Can be configured. The switch key can also be used to change the operating mode of the thumbwheel. Switch keys can also be used in conjunction with floating pointers to select characters and menu items. In this embodiment, the user can make all possible selections while keeping his hand almost still on the thumbwheel or switch key. The use of switch keys in conjunction with floating pointers facilitates the use of small fonts. The switch key is also conveniently provided on the case 12 and built in as an additional hard key. It will be apparent to those skilled in the art that there are many ways to combine menu selections, key toggles, and I / O configurations to provide a convenient user interface to the user. Another embodiment of the present invention provides an I / O configuration application that allows a user to completely customize the characteristics of a display device in an I / O area. Alternatives to the described thumbwheel include other types of mechanical interfaces that can be used to provide pointer-type input in different embodiments of the present invention. One is a four-way force-sensitive mouse button and selector button, which can be located at both ends of the case 12 under the I / O interface 16. Each button is designed to be actuated by one finger. Four-way force-sensitive mouse buttons provide a menu to scroll the cursor and pan and / or index the keyboard and document window, while selector buttons are used to select and edit according to the position of the cursor. This configuration minimizes hand movement and keeps the I / O area clear for observation. The use of thumbwheels, pressure sensitive switches and buttons, and the like, including the conversion of mechanical motion and pressure to electrical signals, and the provision of such signals to microcontrollers, is known to those skilled in the art. Accordingly, details of such an interface are not described herein. However, such an input combination having a display and an input area is considered inventive. FIG. 5 is a perspective view of a μPDA 10 connected in place in a notebook computer 172 via a type II PCMCIA connection port 10 5 in accordance with an embodiment of the present invention. As will be described in further detail below, when the μPDA is linked, it operates, manages communications, and begins processing at the host computer, which certifies memory access rights (protection). Access rights are considered important by the inventors for a number of reasons. First, one or more specific code means are specific to each μPDA, but the user can protect the files stored in his module from being accessed by unauthorized persons. The code can be used to control access to both data and files through the I / O interface 16 and through the body bus interface, so that data and files are protected from access by unauthorized body systems. Can be protected. In the above case, when the μPDA is powered on, the application routine queries the user for the access code entered at the I / O interface 16 (see FIG. 4). If the code is not entered properly, access is denied and no power is given. The code for the purpose may be stored in EEPROM 31 (see FIG. 3), or in any case the ROM device may be dedicated to that purpose. In some embodiments, the code is mask programmed at the time of manufacture, so it is immutable. Alternatively, the code may be accessible and modifiable by a particular procedure in the field. In the case of body communication, a portable or desktop computer, or other device, may not be configured to communicate with a μPDA, but may have a connection port physically configured to receive a μPDA. There is also. This is, of course, the case when the μPDA is in the form of PCMCIA. For purposes of disclosure and description, this specification will refer to such devices as general body devices. If the host device is configured to communicate with a μPDA, it is an enabled host device. If the host is configured for full access to a particular μPDA, it is a dedicated host. If the connection device is a general main unit, no communication is performed unless the person providing the μPDA gives a control routine to the main unit. This can be done through a connection port from a separate memory card, eg, by transfer from a floppy disk in a typical main unit, or, in one embodiment, the communication software is connected to the memory 13 of the connected μPDA (see FIG. 3). And can be transferred to the main unit to facilitate another communication. If the coupling device is in fact an enabled main unit or is configured into an enabled main unit after connection, the stored code in the EEPROM 31 (or other storage device) Can be used to prove approval for data and program transfer. In one embodiment, this procedure is performed in the following order. First, when one connects the μPDAs at a compatible connection port, certain pin connections convey both to the microcontroller of the μPDA and to the main CPU to which the module is connected. In the enabled host device, the fact of connection initiates the initialization protocol in both systems. In most embodiments, if the coupling device is other than the main body, ie, cannot communicate with the coupled module, nothing will happen and the user can easily remove the coupled module. If the computer is an enabled body, the application is started to perform body access to the µPDA data file through the µPDA microcontroller. The user interface, described more fully below for certain embodiments, is displayed on body monitor 104 (see FIG. 5). The body interface menu, and other application menus, can be partially formatted as a display of the μPDA I / O interface 16 as shown in FIG. 4 and described in the accompanying text. . In some embodiments, the linked μPDA can operate in place by manipulating the input area of the μPDA displayed on the body screen. If the host device is not a home device for the connected module, that is, if the embedded ID code does not match the code stored in the connected module, the visitor protocol is started. In this case, the visitor menu is displayed on the main body display device 104 for another input, such as a password question for selecting a limited data access area in the linked module. Again, the user can gain full access to the memory registers of the linked module by entering the appropriate password. If the main unit is a fully compatible main unit home device, full access to the main unit can be immediately granted to access the memory contents of the linked module including the program area, and the data and program Both are interchangeable. In some cases, when the μPDA is removed or removed from the connection port, the on-board module microcontroller again gains complete control of the internal μPDA structure. FIG. 6 is a simplified block diagram of a μPDA coupled to a host computer, and FIG. 7 is a basic logical flowchart of the steps involved in coupling a μPDA in a host computer 66 according to an embodiment of the present invention. The host computer 66 has a main CPU 24, an input device 60 such as a keyboard, a mass storage device 28 such as a hard disk drive, and a system RAM 62, and is shown in the most general form. Many body devices have even more sophisticated structures, and it will be apparent to those skilled in the art that the structures shown are exemplary. When the .mu.PDA device is mated, the connector 14 'of FIG. 6 comprises the portion 14 shown in FIGS. 1B and 3, and the mating connector portion (see FIG. 5) which mates the portion 14 at the port 105. The coupling of the separate parts of the connector provides a direct connection between the bus 26 in the µPDA and the bus 26 'in the body. Therefore, there is a direct bus route between the microcontroller 11 and the main CPU 24 (see FIG. 6). As explained above, there is a pin structure (not shown) in the connector 14 dedicated to signal transmission that connects the modules. In FIG. 7, step 42 indicates the insertion of the μPDA module into the connection port. At step 44, the signaling pin structure signals that a physical connection has been achieved. In step 46, the main unit interface bus 26 including the main unit bus 26 'coupled in the main unit is activated. In step 48 (see FIG. 7), the microcontroller 11 in the μPDA initiates a pre-programmed POST procedure. The microcontroller 11 in this embodiment has one page of a RAM 68 configured on a microcontroller chip. In another embodiment, the RAM can be used elsewhere. In step 50, the POST routine loads the bootstrap program into RAM 68, which includes matching code for protection. This code includes, for example, a serial number. In step 54, the bootstrap program starts executing in the microcontroller 11, and in step 56 the microcontroller searches for a password from the main unit on the main unit interface bus 26 (see FIG. 6). In an enabled or dedicated body, the communication routine accessible from the mass storage device 28 in the body, due to the fact of coupling, as described in part above, causes the user interface to be displayed on the monitor screen 104 of the body. Is displayed. It is a communication program that turns a generic main unit into an enabled main unit. In an enabled but not dedicated main unit, the user interface queries the user for the entry of one or more passwords, and after that successive entry, the main unit is accessed from the serial number, and possibly EEPRO M31 in the μPDA bootstrap. The input is sent to the microcontroller 11 for comparison with the other codes entered. According to the code sent from the main unit to the connected module, the microcontroller 11 grants the main CPU full access to the memory 31 in function 52 of FIG. Restricted access at several levels defined by the code (or code that does not fit at all). The access protocols and procedures that allow partial or direct access to the μPDA memory 13 are procedures that are very well known to those skilled in the art, such as bus management techniques, and need not be reproduced here in detail. Absent. In addition to a simple comparison of the codes, there are other techniques that can work together to improve the integrity of security in the communication between the μPDA and the host device. For example, within the storage capacity of an EEPROM or other non-volatile source, the executable code may be a code key used in on-board RAM 68, or code executable from other sources, or a relatively simple map. Each μPDA may be literally a unique device as it is uploaded to the redistribution memory location and the like. As part of the communication routines introduced above, additional unique features have been provided in one aspect of the present invention. One such feature is that, under the control of the host system, where the body has direct bus access to all memory systems, automatic updating and mutual updating of existing and new files on both computers. Is to do a reference. Auto-update is like an automatic update with only a clock sign, a flag for new files before transfer, and an editor that allows users to review both old and new files before choosing a newer file and discarding the older file. There are various options. Automatic or semi-automatic updating of files between the satellite and the body address is a long-standing problem. The update routine may also incorporate auxiliary options to preserve older files. Another useful feature in the body / μPDA communication is the means by which the user selects and configures the joint executable program file for downloading to the μPDA, replacing or replacing those executable routines that already exist. to add. The user may have several different program listings for downloading as a batch, effectively configuring the applicability of the μPDA among various possible working environments. Travel files such as databases, spreadsheets, documents, currency exchange devices, faxes, and other communication programs, time clocks, addresses and call records, and the like, include customized lists of user-preferred applications be able to. In another embodiment, the uncoupled μPDAs can transfer data directly to the body via an optional expansion bus 40 (see FIG. 3). In the special case of a μPDA user who does not have access to the PCMCIA interface in the host computer (notebook or desktop) of the host device, the user connects to the host device via an auxiliary port on the host device such as a serial port and an expansion bus interface. Can be connected. In this case, the μPDA still requests a password from the main body and controls access to the on-board memory according to the received password. An optional extension interface can also be used in some embodiments, while the µPDA is managed by the body, which can effectively transmit data through the µPDA's bus structure. Additional aspects and features Software vending equipment: In another embodiment of the present invention, a software vending device is provided having a very large electronic storage capacity, wherein a user of a μPDA connects a module and purchases and downloads software routines compatible with the μPDA environment. be able to. FIG. 8 is a perspective view of a vending machine 61 having a connecting bay 63 for μPDA, a credit card slot 65, and a bill slot 67. Display 69 includes a user interface for reviewing and purchasing software from a vending machine, along with a selection device button 71, such as button 71, along the side of the display. In another embodiment, the display device also has a touch screen, which in some embodiments can emulate the I / O area of the μPDA on a larger scale. In operation, in this embodiment, the user connects the μPDA device in the vending device and reviews the software for sale only by selecting from a menu on the display 69. The menu allows the user to view and review all available applications or to list new applications after data entry. The user can select certain applications, at least try them out in a simulation, and select an application to purchase. When all requirements, such as proper identification and payment, are fulfilled, the vending machine will select the application selected on the floppy disk supplied by either the user or the vending machine to the memory of the μPDA or, alternatively, the user. Copy In this case, there is a floppy disk drive 73 in the vending machine and a port 75 for distributing formatted floppy used by the customer in the disk drive. This aspect is useful when the μPDA is loaded beyond the capacity to receive the desired software, or when the user simply wants to configure the software synthesis from his own host computer. Providing auxiliary options so that the user can instruct the vending machine to read all or selected customer files before setting new files or data and copy them to one or more floppy disks Can be. As noted above, each user's μPDA includes an EEPROM or other storage device that uniquely identifies the μPDA by a serial number or other code, and in this embodiment, the vending device is in one of several modes. It can be configured to provide software. The user does not give the full capabilities of the application at a very nominal price, but can buy a demo copy of the application that gives the user the opportunity to test the application before purchasing and give it a familiarity. Further, the user can buy one form of the same application that is configured for the ID key of the μPDA to which it is loaded and that is configured to operate only on that μPDA. In another embodiment, the software has the ability to be transferable between keyed µPDA groups or to "unlock" for a limited number of times. In these cases, the application is sold at a lower price than the unlocked one. The unlocked one operates in the μPDA and / or body / μPDA system. A higher priced unlocked one compensates for the likelihood of an unauthorized share of the application being sold. The vending machine can also supply a keyed configuration ordered to operate on the µPDA alone or on a group of µPDAs coupled to the software vending machine. This keying is possible due to at least the individual unique features of each PDA having a unique serial number, and as described above, the vending machine will be able to access the specific module from which it is purchased. It has other protection programs that allow you to prepare and download ordered copies of applications that run only on. As will be apparent to those skilled in the art, there are many different means of achieving a unique response. The standard form stored in the memory device of the vending machine can be re-edited, for example in downloading, using a unique code from the μPDA which is concatenated or identified as a key in the editing, so that only certain μPDAs The program can be run by using the same unique key to sequence commands while running. The keys to scramble or otherwise order the application may also include other codes and / or sequences of executable codes uniquely stored in the μPDA. In yet another aspect related to vending equipment, there is a printer output 77 that prints a hardcopy manual for the user. Of course, the software sold does not need to be specific to the M-PDA. Applications are also sold to other types of devices and are carried in the memory of the µPDA or by flip-flops or the like. In this embodiment, users other than the μPDA can obtain a wide range of software. The software vending device can function as an optional information display center at locations such as airports, train stations, conference halls, and hotels. When inserting the μPDA, the user interfaces directly with the local, national and global news: stock quotes and financial reports, weather, transportation timetables, roadmaps and interpreters, currency exchange applications, email And uploading up-to-date information including, but not limited to, direct online services. The ordered vending device is tailored for commercial travelers and allows users to quickly access relevant information that allows them to download files for transmission via email. In another aspect of the invention, vending devices are coupled so that users can send messages to one another to associates traveling through the location of the associated vending device. Such a dedicated μPDA email is immediately downloaded to the specific μPDA when it is concatenated. The sender may have a uniquely coded key of the partner's μPDA as an identifier, or other dedicated means of identification for email. In another embodiment, as each business partner arrives at the airport, the person activates the customer's vending equipment at that location via an optional installed infrared interface (not shown) on the μPDA. be able to. The customer's vending machine, further equipped with infrared communication, receives the signal and sends and / or receives the waiting message. Enhanced display: FIG. 9 is a plan view of an enhanced I / O interface 79 according to aspects of the present invention. The interface device 79, having about 5 inches diagonally, comprises a combined LCD display at least partially superimposed by a touch-sensitive input screen provided with an I / O area 80 in much the same way as a μPDA. Four connecting bays 81, 83, 85, and 87 are provided on the left and right edges of the interface device 79 in this embodiment and are configured for PCMCIA Type II modules. One of these bays is used to connect μPDAs in accordance with the present invention, and the other three connect functional PCMCIA modules to provide larger CPUs, additional memory, battery power, and modem power. Give such peripherals, and the like. The interface device 79 is a framework for forming a dedicated computer by connecting PCMCIA devices including a μPDA according to the present invention. In other embodiments where μPDA is another type of factor, the connecting bay can be correspondingly formed. The linked μPDAs in this embodiment are configured to create an I / O display in the I / O area 80. The thumbwheel in the M-PDA is accessible but linked, in which case it operates in independent mode as described above. In another aspect, the enhanced display is a touch screen only, and / or from an additional hardware selection device button and / or a standard keyboard located on the enhanced display, via a dedicated bus port, or further. It has a reconstructed output that allows the user to manipulate data through the extended port of the configured μPDA. In another embodiment, the enhanced display device has a dedicated mouse port and / or a dedicated thumbwheel. In yet another embodiment, the interface device 79 comprises an inexpensive ordinary replaceable battery and / or a rechargeable battery. Further, in another embodiment, the interface device 79 can link cross-reference data files between two or more individual μPDAs and a unlocked file according to a control routine that can be manually manipulated. Still further, the interface device 79 can be connected to a keyboard as an input device and positioned and structurally supported for easy viewing on a dedicated keyboard of standard or smaller dimensions. The keyboard then automatically functions as an input device. The interface device 79 for the μPDA provides a computer that is small and compact enough to fit into a second bag or luggage, and is very convenient but very powerful. Microphone / voice recording: FIG. 10 is a plan view of the μPDA 110 having the I / O interface 116, the expansion port 120, and the main body interface connector 114. The μPDA 110 has all of the above features and additionally has a microphone 88. In this embodiment, the control routine in the μPDA uses a linear predictive coding (LPC) method that converts the analog input from the microphone into a digital voice recording. This method uses the least amount of memory, but can reproduce sound input such as real voice within recognizable limits. In another embodiment, for higher quality audio recordings, a two-stage integrator can be used to separate analog signals and synthesize a closer digital representation. Since the μPDA is so configured, the user's voice recording can be recorded and then uploaded to the body for processing. In future embodiments, the digital signal may be converted to text or sent as voice mail over a network. In yet another embodiment, the microphone is integrated with the speaker for editing. Cellular phone interface: FIG. 11 is a perspective view of a μPDA 10 connected to a dedicated cellular telephone device 45 according to an embodiment of the present invention. The telephone device 45 has a connection port 49 for a μPDA according to the invention. In this embodiment, the port 49 is located on one side of the telephone device 45 and has a window 51 for accessing the μPDA I / O interface 16 after it is connected. When the μPDA is connected, all of the software and memory of the μPDA is available to the telephone device, and the telephone device can be operated by the I / O interface 16. In this aspect of the invention, specific control routines and display configurations are provided to enhance the use of the cellular telephone device. For example, telephone numbers collected by the user, associated credit card numbers, access codes, etc., are all readily available and can be quickly and conveniently accessed and used. In one aspect, a simple input displays the selected character, and once the character is selected, a partial list of the called party is displayed. Touch input or use of the thumbwheel on the μPDA can scroll through the list and select the highlighted input. No need to display phone number. When the called party is selected, the µPDA dials a call containing the necessary credit card information stored in the µPDA's memory for this purpose. In another embodiment, the call is timed and time stamped, and a comprehensive log is recorded with the recording area during and after recording. In another embodiment, the conversation is digitally recorded and filed for further processing. Future embodiments may include an audio compression program in the body or in the cellular telephone device 45. Compressed audio files, such as messages distributed in a voice mail system, are downloaded to a µPDA or maintained in a larger memory format in a cellular telephone device. The μPDA can then send the file to the optional expansion bus 40 via a dedicated modem located on the body or corner 20 (see FIG. 6). In this particular embodiment, the cellular telephone device has a port on a bus for digital transmission. In this case, the compression algorithm, together with the audio system control routines, is set at the receiving end of the transmission to decompress the signal and distribute the individual messages. In another embodiment, voice messages are compressed in a wireless format, semi-automatically by distributing them automatically to a dedicated receiving body, or semi-automatically by manually prompting an individual voice mail system before each individual message. Can be transmitted from the cellular telephone device in an uncombined digital composite form. In another aspect of wireless transmission, the microphone / voice recording μPDA as in FIG. 10 can transmit the previously stored voice recording after coupling at the cellular telephone device interface. In Europe and Asia, the telephone equipment systems used are operated on a digital basis, and local stations with compatible cellular telephone equipment can only access the station by being within the active area of the substation. It includes a substation and is known as CT2. In one aspect of the invention, a CT2 telephone device is provided with a docking bay for a µPDA and is configured to operate with a µPDA. In yet another aspect of the invention, in a telephone system applicable to CT2 telephone systems, and other digital telephone systems, the use of compression as disclosed above is performed prior to transmission in the CT2 telephone system. Digitally compressing a message. It is generally assumed that the proprietary compression algorithm can compress a 10 minute voice message into 1 minute using existing CT2 technology. This saves a great deal on telephone usage. In this aspect, a compatible decompression device is required at the receiving station, which is preferably incorporated into a standard μPDA voice mail system for CT2 or other digital transmission. In another embodiment, a control routine is provided to enable the microphone / audio recording μPDA shown in FIG. 10 to carry a compressed or uncompressed digital audio recording. In this embodiment, the μPDA can transmit digital audio recordings in a compressed form when coupled to a CT2 compatible μPDA cellular telephone device. Speaker / Pager: FIG. 12 is a plan view of a μPDA 210 having a microphone / speaker area 90 and a pager interface 92 according to an embodiment of the present invention. This μPDA is capable of picking up a pager signal with an installed pager interface 92 and acting as a standard pager alerting the user through a microphone / speaker 90. When a signal is received, the .mu.PDA 210 can be coupled to the compatible cellular telephone device shown in FIG. 11, and the .mu.PDA automatically dials the caller's telephone number. All other aspects are as described for the linked mode in the cellular telephone device. In another embodiment, the speaker / pager μPDA can be prompted to generate a DTMF tone. DTMF tones are generated from the caller's telephone number. The speaker / pager μPDAs can store pager requests in on-board memory. It can also display all pager requests including time and date stamps, caller identification, and other relevant information at the I / O interface 216 if known. In this particular embodiment, the user receives a page and immediately responds with a digital audio recording on the μPDA via the speaker / microphone 90, and then responds from a dedicated μPDA compatible cellular or regular telephone device Can be sent. Wireless infrared interface: FIG. 13 is a plan view of a μP DA 310 having an IR interface 94 according to an embodiment of the present invention. In this embodiment, the μPDA can communicate with an array of conventional devices in a home or office that provides remote control. Signals specific to the device are programmed into the µPDA in learning / receiving mode and filed with user password protection. Once the correct password has been entered, an icon-based menu is displayed in the I / O area 316 in a user-friendly format. The administrative routine first queries the user for a device to access. For example, in resident applications, icons are displayed for things such as overhead garage doors, security systems, automatic gates, VCRs, television devices, and stereos. In another aspect of the invention, a receiving station, such as a host computer or peripheral interface, has IR capability to communicate data from nearby μPDAs directly to the infrared interface. In another embodiment, a μPDA can interface in a cellular network and function as a wireless modem. Peripherals The μPDA can function as a platform for various peripheral accessories via the expansion port 20 (described in FIG. 1B and other figures). When attaching the dedicated pin of the signal microcontroller 11 in the extension port 20 to the peripheral device, a peripheral bootstrap application is executed. An infrared control routine that can reside in the memory of the peripheral or μPDA is executed, and the μPDA I / O interface displays the relevant menu driven options after the link is completed. Scanner FIG. 14 is a plan view of a μPDA 10 having a scanner accessory 55 according to an embodiment of the present invention. The scanner accessory device is configured as a μPDA and makes an electrical connection via the extension port 20. In this embodiment, the physical interface of the scanner is configured to be securely attached to the μPDA. The scanner accessory 55 has a roller wheel 57 or other conversion sensor and interfaces with the μPDA wheel 18 to sense and convert the hand-held scanner generated in operation. In another embodiment, the scanner accessory 55 has a translator that transmits the appropriate signals through the expansion port 20. The scanner bar is on the bottom and one or more batteries 59 are included in the scanner accessory to provide the extra power needed for light generation. In the scanner embodiment of the present invention, scanner accessories 55 having different widths D2 are provided for different purposes. The bar may have the same width as the μPDA or may be 8 inches or more wide to scan the full width of U.S. character sized documents, or international A4 size documents. A unique control routine scans and sets various options such as the width of the scanner bar for the user interface and identifies the file created in the μPDA memory as a result of the scan pass. At 16, operation information is displayed. Scanned data stored in the μPDA memory can be quickly transferred to the main body via the main body interface 14 when the μPDA is connected. A unique routine is provided to automate the process, and the user does not have to search for the file and start the entire transfer process. Facsimile options: FIG. 15 is a plan view of a μPDA with a fax modem module 89 installed according to an embodiment of the present invention. Fax and communication capabilities are provided to the µPDA via a regular telephone line by a fax modem 89 that interfaces to the expansion bus interface 20. The fax modem has an internal circuit for converting the bus state of the expansion bus into a fax protocol and a telephone plug interface 91. In another aspect, the μPDA is coupled to the body and can be used in communicating with a fax modem 89 that performs fax transmission and file conversion of both the body and the μPDA data file. In this case, the fax modem routine is displayed on the main unit monitor. Printer FIG. 16 is a plan view of a μPDA having a Centronics adapter interface according to an embodiment of the present invention. Printer connector 93 couples to extension interface 20 through cable 97 by connector 95. The conversion capability depends on the circuitry in connector 93 and is physically configured as a Centronics connector to couple with a standard port on the printer. Barcode reader and data acquisition peripherals: FIG. 17 is a perspective view of a μPDA 10 connected to a bar code reader and acquisition peripheral device 100 according to an embodiment of the present invention. μPDA 10 is connected to connection bay 149. I / O interface 16 displays information through opening 147 according to the particular data acquisition application. In this particular embodiment, the peripheral device 100 has an IR interface 94, a microphone 103, a scanner port 101 (not shown), a battery pack 105, and a numeric keypad pad 96 configured as a touch-sensitive array. . Depending on the application routine, the data acquisition peripheral can operate, for example, as a mobile inventory controller. The user can scan the bar code label with the scanner 101 and enter information such as counts at the keypad 96 or by voice input via the microphone 103. Since the application of the peripheral device 100 is very specific, only a limited speech recognition system is required. The speech recognition system can also prompt other command routines within the management application. Once the inventory has been collected, a database is displayed and further manipulated directly via the I / O area 16 in the opening bay 147, or the information is quickly downloaded to a nearby body via the IR interface 94. Can be Instead of frequent data transmission, the data can be stored in an optional auxiliary memory location in the peripheral device 100. In another aspect, a data acquisition peripheral can be interfaced to an analog output of a monitoring device, such as a strip chart recorder, to digitize and store incoming analog signals. Solar battery charger: FIG. 18 is a perspective view of the μPDA 10 viewed from the opposite side of the I / O interface having the solar battery charger panel 98 according to an embodiment of the present invention. When the μPDA 10 receives strong light, such as sunlight, the panel 98 is arranged so that the solar cell charger absorbs solar energy and converts it to electrical energy for the rechargeable battery 15 in the μPDA. The solar battery charger 98 can be permanently wired to the circuit of the μPDA or installed by other means and connected to a dedicated electrical port or an expansion port. The solar cell charging device is arranged so that the μPDA device connects the panel to the connection port in place. In another aspect, the pluggable device may be unplugged before connecting the μPDA, and the removable charger may be a larger surface area. Game / Conference Center: FIG. 19 shows a game center device 33 according to an embodiment of the present invention that connects several μPDA devices (37, 39, 41, and 43) to play a competitive and interactive game by a plurality of μPDA users. It is an enlarged view. Game center device 33 is controlled by an 80486 CPU in this particular embodiment. The μPDAs can be connected to the central unit by a cable connection, through an expansion bus or through a connector, such as connector 35, through the body interface of each μPDA. Although the figure shows four connectors, two and any number of two or more may be used. According to another aspect of the present invention, a game center can function as a conference center where multiple μPDAs can exchange information. In this manner, for example, with custom routines stored and executable on central device 33, the administrator can provide the product database, spreadsheets, price sheets, job assignments, customer profiles, address book, telephone directory, travel itineraries during a meeting. , And other related business information, can be updated for a number of merchant μPDAs. Standard keyboard FIG. 20 is a perspective view of the keyboard 151 connected to the μPDA 10 via the extension port 20 by the cord and the connector 153. In this example, the keyboard is a mechanical keyboard having a full-size standard key array and a built-in controller and interface to communicate with the μPDA. In another embodiment, the keyboard may take many other forms, including a two-layer flexible roll-up keyboard as described in US Pat. No. 5,220,521. In addition to a keyboard, another input device, such as a writing tablet, may also be interfaced to the μPDA via the expansion port 20. There are various additional ways to combine different embodiments of the µPDA for useful functions. For example, an IR-equipped μPDA attached to scanner 55 can transfer a large amount of graphic files to a host computer in near real time. If the file is text, then the host will automatically process the file with an optical character recognition (OCR) application and send a greatly reduced ASCI file back to the μPDA. As mentioned above, μPDA-based devices set up software security and distribution protocols and have bus capabilities managed by a host computer system for various applications. Flexible roll-up keyboard As computer systems have become smaller, the ability to provide suitable input devices, such as keyboards, used in smaller portable systems has become a problem. 20 and the description relating to FIG. 20 show a full-sized keyboard used in a μPDA according to the present invention. While such a keyboard allows the user to provide keyed input to the µPDA's memory, it has the disadvantage that the keyboard is still less portable than the µPDA itself. In one aspect of the present invention, there is provided a flexible keyboard that can be rolled up for transport and storage, and in one embodiment is cordless, which communicates with a μPDA via a code transmitted in a dynamic magnetic field. . The following describes such a keyboard and inductive coupling technology for cordless communication. FIG. 21A is a plan view of a flexible roll-up keyboard 1011 according to the present invention. FIG. 21B is a side view of FIG. 21A. In the embodiment illustrated by FIG. 21A, the keyboard has a layout according to the popular "IBM Advanced" format. The flexible keyboard of the present invention can be configured in any format that is convenient. In this embodiment, the dimensions are about 50 cm in length and about 20 cm in width. The keyboard is formed by two molded layers of a flexible material such as polyurethane. However, there are many other suitable materials, including natural rubber and some types of synthetic rubber. The upper layer 1013 is shaped as a key pad and the lower layer 1015 has conductive traces that form circuits that transmit keystrokes to control circuit modules 1017 located in pockets between the layers. In some embodiments, the batteries may also share a pocket, or may be transported in a similar pocket elsewhere between layers. In the embodiment of FIGS. 21A and 21B, two flexible layers joined by a flexible appendage from the other layer that “snaps” to the receptacle of one layer allow the keyboard to be rolled for transport or storage. Relative motion between layers when raised. In the following, key cells, conductive traces, layer connections, etc. will be described in more detail. FIG. 21C shows the flexible keyboard 1011 of FIG. 21A wrapped around a compact cylinder and secured by a band 1019. In this figure, the band is a simple plastic cylinder, but could be any number of other devices such as rubber bands, cords, Velcro loops, and the like. Several methods exist, and a fastener may be attached to the keyboard to keep the keyboard in a roll-up state, such as a Velcro pad bonded by an adhesive. FIG. 22 is a perspective view of a single key cell 1021 in a flexible keyboard according to the embodiments of FIGS. 21A and 1B. The key cell is based on a dome shape 1023 molded into the top layer 1013 and provides the necessary vertical movement to provide contact closure for keystrokes and prevent other closures. The molded dome shape includes a finger pad 1025 molded on top of the dome. The finger pad has a concave top surface with a letter or letter symbol such as the letter "A" shown in FIG. 22 provided on the top surface. The letters or letters may be silk-screened, printed, or provided by a number of other techniques known in the art. Alternatively, the letter or character may be molded into the surface as a recess below the height of the finger pad surface, thereby minimizing wear of the letter or character due to repeated use. In addition, there is a "breath" hole 1027 through the side wall of the dome structure to allow the air under the dome to escape when a keystroke is made. The dome collapses when the user presses it, and returns to its original shape when the pressure is removed. That is, the "normal" position of the dome is in an uncrushed state. FIG. 23A is a cross-sectional view of the key cell taken along line 23A-23A of FIG. The lower layer 1015 and the upper layer 1013 are joined by a bonding technique (not shown) so that each dome structure in the upper layer 1013 is located on a corresponding conductive structure in the lower layer 1015. Hereinafter, the joining technique will be described in detail. The lower layer 1015, shown briefly above, has conductive traces that transmit keystrokes to the control circuit module 1017 and encode signals transmitted to the computer. FIG. 23B is a plan view of layer 1015 in the key cell in the direction of arrow 1029 of FIG. 23A. The dotted circle 1031 represents the outer peripheral position of the dome structure 1023 of the upper layer 1013. Near the center of the dome structure region, the lower layer 1015 has a protruding portion 1033 that is also recognized as protruding in FIG. 23A. The upper surface of protruding portion 1033 is conductive in regions 1035 and 1037, but not in central region 1039. Conductive trace 1041 connects to conductive region 1035, and another conductive trace 1043 connects to conductive region 1037. The higher protruding portion 1033 of the surface of the lower layer 1015 is primarily for convenience rather than required. There are also a number of ways in which conductivity can be imparted to conductive regions. For example, a conductive trace can be formed by coating the entire surface with a conductive material, and then removing the material to form the trace. The conductive material can be molded into a flexible material, and other methods exist. In FIG. 23A, the contact closure protrusion 1045 on the lower surface of the finger pad 1025 is similar to the protrusion 1033 on the lower layer 1015 and is located just above the portion 1033 when the layers 1013 and 1015 are joined. You. The underside of the protrusion 1045 is also conductive, forming a contact closure element that selectively causes an electrical closure between the conductive traces 1041 and 1043 when the user presses the dome 1023 by finger pressure. Due to the contact closure, the signal to be transmitted to the control circuit module 1017 is coded for that purpose. Traces and other areas of conductive material can be formed on the flexible surface of the molded layer in a number of different ways. In the embodiments described herein, these conductive regions may be provided by a conductive resin-based coating formed in a conventional manner, such as silk screen and other masking techniques. It will be apparent to those skilled in the art that numerous variations can be used for the sidewalls of the dome of an individual keycell. For example, the thickness and angle of the wall can be changed to change the force required to perform a keystroke, which affects the "feel" of the user's keys. Similarly, key cells can be designed with different distances between the protrusion 1033 and the protrusion 1045. As shown in FIG. 22, a vent 1027 may be provided in the dome 1023 to allow air to escape from the key cell when it is pressed. The feel of the keystrokes can also be changed by changing the number or size of the vents 1027. It is evident in the plan view of FIG. 21A that there are several different sized and shaped key cells in the keyboard pattern, rather than the key cell size and shape shown in FIGS. 22, 23A and 23B. Enter key is one example. In these cases, substantially all of the top surface is a finger pad, and the walls and upper portion are designed to provide the same resistance to operation as a small key cell. For these large key cells, a more expensive contact closure pattern is provided on the protrusions of the lower layer 1015 than the simple pattern shown in FIG. 23B, and a corresponding contact closure pad is provided, where the user presses the finger pad. Regardless of the keystroke achieved. FIG. 24A is a plan view of the lower layer 1015 at the position of the entry key, and illustrates this principle. In this figure, the upper layer 1013 has been removed. In FIG. 24A, a dashed line 1047 represents the area of the entry key on the keyboard of FIG. 21A. The protruding portion 1049 is shaped to cover a central area surrounded by the extended key cells. Regions 1051 and 1053 are conductive, and region 1055 between the conductive regions is non-conductive. Trace 1057 connects to region 1053 and trace 2059 connects to region 1051. FIG. 24B is a plan view of the upper layer 1013 at the same position as FIG. 24A. Line 1061 is the limb of the dome area for the entry key, and line 1063 is the limb of the finger pad area. The dashed loop 1065 is the loop of the contact closure protrusion on the lower surface of the upper layer 1013 that matches the shape of the protrusion 1049 in FIG. 24A. The underside of the contact closure projection is conductive as described for the single key cell of FIG. 23A. With this configuration for a contact closure configuration, large areas can function as small areas. It will be apparent to those skilled in the art that the same long linear contact closure structure described for the enter key is valid for the space bar, and that other shapes can be applied to other keys. The keyboard of the invention described thus far is what is known in the art as a "hard touch" keyboard, which simply means that the keystrokes are contact closed. The "wiring" provided by the conductive traces described above constitutes a conventional matrix circuit commonly used in the art for such keyboards. The matrix circuit may be connected to a built-in microprocessor that encodes the information for "reading" the contact closure and transmitting it to the computer. Similarly, the matrix circuit can interface with a multi-lead cable for connecting to a computer, and the controller that translates keystrokes into digital data for the computer data bus resides in the computer itself, not the keyboard. be able to. FIG. 25A is an exploded perspective view of the end of a flexible keyboard in which control circuitry can be housed, showing layers 1013 and 1015 separated to show internal details. The lower layer 1015 has a pocket 1067 that locates and holds the control circuit module 1017, and the upper layer 1013 has a pocket 1069 that aligns and holds the control circuit module when the layers are joined. . Conductive traces 1071 are associated with individual key cells and include the conductive traces described above arranged in a conventional matrix to signal the contact closure of individual keys and key combinations. This trace is formed on the surface of the lower layer 1015, wraps around the edge of the pocket 1067, and runs down the sides of the pocket to form contact pads that interconnect with the control circuit module 1017. FIG. 25B shows the control circuit module 1017 viewed at an angle of about 90 ° from the direction of the drawing of FIG. 25A. The control circuit module 1017 is shown as a stored device that includes a microprocessor and associated circuitry that monitors key operations, encoding operations, and transmission of encoded data to an associated computer. Contact pads 1073 formed from a metal conductor material such as a wire or strip are stored with module 1017. Module 1017 includes conventional control circuitry commonly used in the art to encode keystrokes into key closures when transmitted by a conventional wiring matrix for transmission to an associated computer. FIG. 25C is a view of module 1017 in the direction of arrow 1075, showing the configuration of contact pad 1073 for module 1017. Contact pad 1073 is formed to extend from module 1017 to one side, such that when module 1017 is inserted into pocket 1067, contact pad 1073 is pressed against trace 1071 on the side of the pocket. Thus, electrical contact is made between the contact pad 1073 and the trace 1071. The structure shown allows relative movement between the elements when the flexible keyboard is rolled for transport or storage without damaging the conductors or other elements. The keyboard 1011 of the present invention has been described above as having two layers, and it is desired by the inventor to facilitate the matrix connection and other details of the present invention. When the keyboard is rolled as shown in FIG. 21C, some relative movement between the layers has been found to be effective. Therefore, the keyboard layers 1013 and 1015 are connected by providing a receptacle opening on one layer and a connector extension on the other layer. The protrusion 1075 from the lower layer 1015 and the opening 1077 in the upper layer 1013 as shown in FIG. 25A are examples of such connection means. FIG. 25D is a cross-sectional view taken along line 25D-25D of FIG. 25A, where layers 1013 and 1015 have been combined. The opening 1077 is formed in the shape of a truncated inverted cone when the layer 1013 is molded, and the protrusion 1075 is formed in the same shape when the layer 1015 is molded. The molded protrusion is forced into the opening to join the two layers. When the keyboard is later rolled, the protrusions bend, allowing limited relative movement between the layers. It will be apparent to those skilled in the art that there are other essentially equivalent ways of joining the two layers. For example, openings can be provided in both layers, and separate flexible connectors are inserted into aligned openings to hold the two layers together. Similarly, there are a number of different shapes that may be used as protrusions or connectors and openings. To function as an input device for a computer, keystrokes need to be communicated with the computer. In one embodiment, the keyboard 1011 of the present invention, as described above, includes a controller that transmits codes to the computer and indicates keystroke and pressed key combinations. In the embodiment of FIG. 25A, a connector receptacle 1079 is formed in layer 1015 when the layer is molded. The connector cable 1081 has an end 1083 configured to be located in the receptacle 1079. Conductive traces 1085 similar to the matrix traces described above are formed in the lower layer 1015 between the pocket 1067 and the receptacle 1079 along the vertical walls of both openings. Module 1017 has contact pads (not shown) on the end facing receptacle 1079, which are similar to contact pads 1073 shown in FIGS. 25B and 25C. Similarly, cable end 1083 has contact pads 1087 that contact conductive traces in receptacle 1079. The other end of cable 1081 has a connector that mates with a computer receptacle, such as an AMP connector. FIG. 26A illustrates another embodiment that communicates with a suitably equipped computer without cables. Layers 1013 and 1015 have pockets 1089 and 1091, respectively, that determine and hold a battery 1093 that connects to control module 1101 by traces 1098 between pockets, similar to the traces described above with respect to another connection. The battery is approximately the width and height of the control module to facilitate rolling of the keyboard. At the other end of the pocket 1067 for the control module 1101, a pocket 1095 in the lower layer 1015 and another pocket 1097 in the upper layer 1013 are driven by the output signal from the control module 1101 through the connection trace 1098 as described above. It holds a stored magnetic coil 1099 without a driven core. In this embodiment, the coil is driven at a controlled frequency and the data to be transmitted to the computer is encoded in the changing magnetic field generated by the coil. A sensing coil in the computer senses the coded data, decodes it, and provides it to the computer bus as digital data. Hereinafter, inductive coupling will be described in more detail. Another means of transmitting data from the keyboard 1011 to the associated computer is a coded light transmission. In this embodiment, the optical transmitter is replaced by a coil 1099 and the control module 1101 drives the transmitter to transmit the coded signal to a receiver in a computer. Coded light transmission is known in the art as sending data from a keyboard to a computer. FIG. 26B shows yet another embodiment without a local control module. In this embodiment, conductive trace 1071 reaches pocket 1102 formed in layer 1015, and connector 1100 and cable 1104 have a number of conductors equal to the number of conductive traces. The connector is located in pocket 1102 and keystrokes are transmitted through a cable to a computer (not shown). A controller in the computer that is not part of the keyboard translates the keystrokes, digitizes the data and provides the data to the computer bus. This embodiment has the disadvantage of requiring a cable with more traces than in the form of a built-in control, but has the advantage of no control in the keyboard. FIG. 27A shows a flexible keyboard 2103 according to the present invention connected to a computer 1105 by the transmission cable 1081 described above. The computer may be of many types, including the popular desktop model. Computers that use a keyboard typically include a CPU and an electronic storage system such as a hard disk drive connected by a bus system to the CPU and other devices, and may have a display terminal. FIG. 27B illustrates a flexible keyboard 1107 according to one embodiment of the present invention where the code is transmitted by a magnetic field and coupled to a computer 1109. The computer in this case is a coil that senses the magnetic field 1111 generated by the keyboard transmission system, and a demodulation system (shown) that decodes the transmitted data and supplies it to the computer's digital bus for use by the CPU. Not). Although the coupling devices and techniques are applicable to flexible keyboards, inductive coupling will be described in more detail below with a rigid keyboard as an example. It will be apparent to those skilled in the art that numerous changes may be made to the embodiments shown without departing from the scope of the invention. Numerous differences within the scope of the present invention have been set forth above. For example, there are many suitable materials and key cells can be formed in many different ways. The traces are routed in a number of different ways, are formed of a number of different types of materials, and the pockets are located at different locations for the elements of the keyboard. Such differences are to be considered within the scope of the present invention. Conductive coupling FIG. 28 is a perspective view of a general-purpose portable computer having a keyboard connected by the guidance device according to the present invention. The computer system of FIG. 28 includes a basic device 2013 including a housing 2017 and an inclined display device 2019. The display may be one of several types of flat panel displays available. Housing 2017 houses the main electronics that operate such elements as a CPU microprocessor, I / O bus, and system Ram memory. There are connectors (not shown) that connect to serial devices and the like, which are typical of portable computers. Separate keyboard device 2015 performs alphanumeric and other keystroke input without the aid of a cable connection by encoded information transmitted in a magnetic field represented by magnetic field lines 2021. FIG. 29 schematically shows some of the internal elements of the keyboard 2015. In this particular embodiment, the key switches (hereinafter referred to as keys) are connected in a matrix 2023 and scanned by a microprocessor 2025 included within the keyboard framework. The scanned matrix arrangement greatly reduces the number of I / O port bits required for a very large number of keys. This scanned matrix arrangement is only one of many conventional means by which a key action can be recognized by an embedded microprocessor and is used here by way of example. The present invention may be combined with virtually any means known in the art for actually recognizing and encoding keystrokes. In addition, there are many other common features of keyboards that are not mentioned here because they have little relevance to the present invention. For example, keyboards typically have a small number of display LEDs that indicate Num lock, Cap lock, Scroll lock, etc., but these features are not described here. The scanned matrix of FIG. 29 shows 16 keys interfaced to microprocessor 2025 through a 4-bit input port 2029 and a 4-bit output port 2031. A pull-up resistor (resistor 2033 is an example) connected to a built-in battery-powered power supply (connection not shown in FIG. 29) is high at the input port when no key is pressed in the row. Supply level. When scanning, the matrix reads one row at a time. One of the output port bits is set to 0, while all others are set to 1. In FIG. 29, the second and lower rows are read. The keys in the row with the output bit set to 1 are effectively disabled, and when the key is pressed, only the high level output port bits are added to the input port bits already pulled high by the pull-up resistor Connect. The key in the row driven by the 0 set bit is active. Pressing any key in the active row pulls the input port bit in the corresponding column. Each row is read and the sequence is repeated indefinitely. The matrix must be fully scanned at a speed that will ensure that the microprocessor does not miss that touch if the user quickly presses and releases the key. In fact, not only the contact made but also the interruption is recorded, which allows the key combination to be recorded. In the schematic diagram shown, the possibility of reading a "ghost" key as a result of the key combination, but this potential problem is addressed by placing a diode (not shown) in series with each key. It will be apparent to those skilled in the art. A sixteen key matrix is given as an example, but can be extended to many more keys in many ways. For example, input and output ports with many bits may be used. One 16-bit input port and one 16-bit output port support a matrix of 256 keys. Alternatively, many ports of 4 or 8 bits may be used. Typically, a full keyboard scan occurs once every few milliseconds. In a conventional keyboard, and in this embodiment of the invention, a built-in microprocessor converts the information obtained from the scan into a hexadecimal scan code. Many types of scan codes can be used, and the invention is not limited by the choice of scan code to be used. In a typical system, the microprocessor sends the scan code serially over a four-wire cable, with one wire transmitting all the data. The main part of the computer in the normal case receives these scan codes on a dedicated I / O port, at which port the keyboard controller chip issues an interrupt command to the CPU used to read the scan codes. Thereafter, the CPU reads the scan code and decodes the keystroke information as input. The program that performs this is typically part of the system BIOS. In the system of the present invention, there is no cable to transmit the scan code to the computer. In the embodiment shown in FIG. 29, the microprocessor 2025 operates a current controller 2035 that controls the current from the power supply 2039 in the circuit 2037. The controlled current passes through a one-turn generator loop 2041 and produces a magnetic field represented by exemplary field lines 2043. In FIG. 29, the generator loop 2041 is shown in plan view, and the magnetic force lines 2043, which are generated perpendicular to the plane of the loop and are typically substantially circular, are seen as lines. FIG. 30 shows the receiver loop 2045 arranged in the generator loop 2041 and the housing 2017 of FIG. The receiving device 2045 provides the function of a special I / O port for receiving a scan code through a serial cable to a normal system, and sends the code to the system CPU. In one embodiment, the receiving device 2045 is configured as an add-in card for a general-purpose computer, but in another embodiment, it is a hard-wired device in a computer housing. The latter is a preferred case for notebooks, laptops and other highly portable computers. In the present invention, information about keystrokes is sent to the system CPU via magnetic changes encoded in the magnetic field 2043. As a result, the receiving device 2045 has a receiving loop 2047 that intercepts the magnetic field generated by the loop 2041. As is well known in the magnetic field art, there is no effect in loop 2047 if there is no change in the strength of the magnetic field. Transmission of information requires that the magnetic field expand or collapse. As is known in the electrical arts, there is a property defined between two electrical circuits called the mutual inductance. Mutual inductance determines the electromotive force induced in another circuit as a result of a change in current in one circuit. The direction of the electromotive force in one circuit is, of course, a characteristic of the current direction in the other circuit. In the embodiment of the present invention illustrated by FIGS. 29 and 30, the current i generated in loop 2041 changes the magnetic field 2043 generated by the change in current in loop 2047 from 0 to i (and from i to 0). ) Change causes an electromotive force V in loop 2047 ₁ Generate To cause a detectable electromotive force change across loop 2047, current controller 2035, driven by microprocessor 2025 (FIG. 29), causes a finite burst of current in loop 2041. When this current goes from 0 to i, a positive electromotive force is generated in loop 2047, and when the current in loop 41 falls back to 0, the magnitude of the electromotive force in loop 2047 changes to a negative value. . In the present invention, the change in electromotive force provides the ability to transmit a scan code. Empirically, the magnitude of the electromotive force generated in another circuit by a change in current in one circuit is proportional to the rate of change of the current with respect to time in that other circuit, ie, di / dt. It is known and is reflected in the concept of mutual inductance. Thus, the cross section of the transmission loop is relatively large so as not to provide a high resistance impedance to the rapid rise in current as a result of applying a voltage to the transmission loop. In this embodiment of the invention, the transmission loop is formed of a square conductor having a side of about 2 mm and an average diameter of about 25 mm. In the illustrated embodiment, the current for the transmit loop and the other operations of the keyboard are provided by a battery-based power supply 2039. Therefore, it is desirable that power requirements for the keyboard be kept to a minimum level. However, transmission by spurious signals generated by the surrounding magnetic field due to current levels in other circuits of the keyboard, computer elements in the housing 2017, or other devices that may be located near the computer system according to the invention It is desirable to operate in such a way as to avoid the deterioration of. In the embodiment shown, the current in the transmit loop is limited to a few milliamps and the interference is handled at the receiving device rather than due to the high power requirements on the transmitter. The electromotive force induced in the receive loop 2047 is preferably monitored by a sensing and demodulation circuit 2049 in the receiving device according to a control routine executed as part of the system BIOS, and the output register 2051 is configured to receive the received signal transmitted from the keyboard. Triggered by the entered scan code. When the scan code is "ready", as in a normal demodulator, the device 2049 issues an interrupt command via the I / O bus 2053 to the system CPU 2055, which can be used to read the scan code. . After the received scan code is read by the system CPU, the output register is reset for the next scan code received. FIG. 31A shows a received electromotive force waveform 2057 (V across the loop 2047) as a result of managing i in the transmission coil 2041 according to a pre-programmed code protocol. ₁ 3) is an example of the trace. FIG. 31B shows a serial bit pattern 2058 generated as a result of monitoring the received electromotive force waveform. In the transmission protocol of the embodiment illustrated by FIGS. 31A and 31B, such as a typical serial protocol, there is a pre-programmed bit time (bt) 2063 that is the reciprocal of the transmission rate (sometimes called the baud rate). This bit time for scan code transmission does not need to burden most system clock speeds. For example, a very modest 10 MHz clock speed is 10 ^-7 It has a period of seconds. For example, assuming a minimum of 1000 times the clock period and a 12-bit time to transmit one scan code, the code would be 1.2 × 10 ^-3 Can be sent in seconds. Few people type that fast. In this embodiment, the protocol consists of an electromotive spike between the ends of the receiving loop generated by current bursts in the transmission loop. The keyboard microprocessor 2025 (FIG. 29) reads both the make and break of the keystroke and the key combination and sends the scan code in a serial burst timed according to the bit time. Each current burst in loop 2041 generates a spike, such as spike 2059 in loop 2047, which spans about one quarter of a bit time, which can vary widely within the bid time. The scan code in this embodiment is a normal scan code for a keyboard compatible with the United States IBM as referenced above, but there are a number of alternative codes that may be used in alternative embodiments. I do. In FIG. 31, the code start signal is provided by three spikes 2061 timed at twice the bit time rate. Circuit 2049 (FIG. 30) recognizes the code start signal, monitors the next 8 bit times for a spike indicating a data bit, and sets output register 2051 according to the sensed bit. Bit times with limited spikes are logic ones, and bit times without spikes are logic zeros. After eight bits have been transmitted, the transmitter issues a five-spike stop code 2065 at twice the bit rate and looks for another start signal. A wide variety of start and stop codes (signals) may be used with different coding schemes within the scope of the present invention, and the described means is only one of many such. The scan code 00101101 sent in the embodiment of FIG. 31 is hex 2D, which is the make code for the "x" key according to the protocol used in the preferred embodiment, and is compatible with most IBM compatible computers. This is the normal scan code used by the keyboard system. When the user types on the keyboard, the system according to the invention continuously translates the make and break of the keys and the key combinations used and sends the scan code to the computer via the transmit and receive loops. It will be apparent to those skilled in the art that many modifications may be made in the embodiments described for inductive coupling without departing from the scope of the invention. The numbers are described above. There are many more. There is wide latitude in other variables such as, for example, the dimensions of the transmit and receive loops, and the timing of the generated current and coded data. Similarly, there are many coding schemes that may be used other than the ones described in the preferred embodiment. Many other variations exist within the scope of the invention. It will be apparent to those skilled in the art that many changes and many other combinations may be made for the μPDA without departing from the scope of the invention. For example, there are a number of ways to construct the support structure of a μPDA and interconnect the active elements. One method is illustrated by FIG. 2 and is described in the accompanying text. There are many alternatives to this preferred structure. The device according to the invention may also employ a wide range of dimensions and shape factors. Although the use of the well-known PCMCIA shape factor is described, other dimensions and configurations may also be provided in other embodiments. In larger embodiments, built-in peripherals may be configured. In addition to these changes, the connection of the μPDA bus can be made in various ways. Although the well-known PCMCIA standard is described by reference, other connections may be used in other embodiments. The type and dimensions of the memory may vary. The means for providing the security code may vary. The characteristics of the internal bus may also be changed. In fact, many variations exist without departing from the scope of the invention.

[Procedure amendment] [Submission date] November 14, 1997 [Correction contents]                                The scope of the claims 1. A die having an internal power supply and a magnetic field generator, and radiated by the magnetic field generator. The keyboard is configured to encode keystrokes in a magnetic field. Cordless keyboard and   An inductive core that receives coded keystrokes in a dynamic magnetic field And a coded key in a dynamic magnetic field connected to this induction coil A decoding circuit for converting a stroke into a standard serial bus data. A card module,   A coupling bay configured to receive and couple this electronic card module The decoding circuit in the electronic card module is connected by a multi-pin connector. And a computer connected to the internal bus of the computer. Computer system. 2. The electronic card module is a personal computer memory card As a Personal Association Card (PCMCIA) 2. The device of claim 1, wherein the device is configured to receive and communicate with a PCMCIA card. Computer system. 3. The PCMCIA card has a container, a local CPU, a memory, and a surface of the container. A digital assistant module having a display device mounted thereon Item 3. The computer system according to Item 2. 4. Coupling bays are laptop, notebook, and handheld computers The computer system according to claim 1, which is one of the following. 5. The keyboard has two cylindrical rolls that can be rolled for storage and transport. 2. The computer system according to claim 1, wherein said computer system is a connected layer flexible keyboard. Tem. 6. Furthermore, it is connected to the local CPU of the digital assistant module, Digital assistant module specific for computers with a bay Identify digital assistant modules that contain codes specific to the digital assistant module. 4. The computer system according to claim 3, comprising a volatile storage device. 7. 7. The computer system according to claim 6, wherein the nonvolatile storage device is an EEPROM. M 8. Digital assistant module is further digital assistant module User having an electrical connection to a storage battery to supply power to the other functional elements 4. The computer system of claim 3, comprising an accessible well. 9. The display is transparent and at least partially touch-sensitive A touch-sensitive screen and display device on one surface of the container. 4. The computer system of claim 3, wherein said computer system forms a substantially flat I / O device. M 10. The digital assistant module also controls the operation in cooperation with the display device. 4. A pointer device for inputting a position and a direction for performing an operation. Computer system as described. 11. The pointer device has a thumbwheel provided at the corner of the container. The computer system according to claim 10. 12. The pointer device has a four-way pressure sensing area on the surface of the container. The computer system according to claim 10. 13. The digital assistant module is also a digital assistant module And an expansion bus interface for connecting the peripheral device to the peripheral device. 2. The computer system according to 1. 14． Induction coil receiving coded keystrokes in dynamic magnetic field And   A coded keystroke in a dynamic magnetic field connected to this induction coil A decoding circuit for converting the data into standard serial bus data,   The electronic card is connected to the connection connector of the host computer connected to the decode circuit. And a multi-pin electrical connector configured to connect. Electronic card module. 15. The electronic card module is a personal computer memory card Cards configured as National Association (PCMCIA) cards An electronic card module according to claim 14. 16. An induction coil in an electronic card configured to be inserted into the coupling bay; Install the decoding circuit,   Insert the electronic card into the coupling bay and put the decoding circuit on the computer connection,   Dyna radiated by the magnetic field generator, having a built-in power supply and a magnetic field generator The keyboard is configured to encode keystrokes in a mic magnetic field. A cordless keyboard   Cordless keyboard at computer-related positions within the dynamic magnetic field Computer having a coupling bay for an electronic card characterized by placing a card How to fit a cordless keyboard.

────────────────────────────────────────────────── ─── Continuation of front page    (72) Inventor Donia, Pascal             United States, California             94086, Sunnyvale, N. Murphy             ー Avenue 374 (72) Inventor Sailor, William Jay             United States, California             95066, Scotts Valley, Rockwood             De Lane 317 [Continuation of summary] Port (20), and expansion peripheral devices can be connected to this expansion port (20). May be connected and operated.

Claims (1)

[Claims] 1. An enclosure for housing and supporting the internal elements;   Digital to manage the functions of the personal digital assistant module A microcontroller in the enclosure for performing operations;   Memory bus structure for storing data and executable routines Memory means connected to the control device;   To supply power to the functional elements of the personal digital assistant module Power supply means in the enclosure of   Operable by microcontroller, configured on surface of enclosure Display means;   Surrounded by the first part of the microcontroller and host interface connector Host interface bus structure connected on the body surface Configured to connect the microcontroller directly to the computer-compatible bus structure Host interface means,   Built-in power supply and a variable magnetic field to transmit keystroke codes Circular for storage and transport having a circuit configured for A flexible keyboard with two connected layers that can   Configured to sense changes in the magnetic field and decode keystroke code transmissions A circuit including an inductive coil in the enclosure. Assistant system.