Abstract:
An interactive data entry apparatus to accept, translate, store, and transmit data entered via a paper data entry form and to simultaneously create a written and magnetic or other computer data record. The apparatus comprises a digitizer upon which a data entry form is placed and a clip which holds the form in place. The digitizer determines the type of form, generates a data entry area corresponding to the form, and accepts check-marks and alpha-numeric data. The apparatus further comprises a microprocessor for storing appropriate data or commands; a stylus; a display to provide visual feedback of entered data; a speaker to provide audio feedback; batteries and wireless communication means to allow portability; and memory and communication ports to provide additional capabilities including communications with a central processor and enhanced local memory capacity. Commands may be entered or activated in the processor be selecting various function keys by activating the stylus above the corresponding function key in the clip&#39;s transparent surface. Further, the apparatus may include an access limiting means to ensure the proper authorship of the data entered.

Description:
This is a continuation-in-part of application Ser. No. 08/084,472, filed Jul. 1, 1993, now U.S. Pat. No. 5,444,192. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to an apparatus for capturing data at its point of creation and in particular to an apparatus for providing data originators with direct control over the entry of data into a magnetic or other computer data recording means and a data processing system. This invention eliminates the need to reenter data collected on printed forms into a computer system. This invention also relates to an apparatus for capturing data which simultaneously creates a magnetic or other computer data record and a written backup copy of the data. 
     2. Description of the Related Art 
     Traditionally, certain information, especially medical information, is gathered during a face-to-face encounter with a patient, customer, or client (hereinafter &#34;data providers&#34;). In situations in which a computer may not be desirable or affordable or use of a computer might be intimidating to a data originator, data may be written on a printed form designed for data gathering by the originator. It may then be entered into a computer for storage and processing by members of a data processing staff. Generally, these staff members do not have the same training and background as that of the originator of the data and were not present when the data was gathered. This process of entering or re-recording the data may result in errors, which could lead to mismanagement of the data, as well as financial, e.g., billing or inventory, or legal problems for the originator. This invention is intended to encourage the originators of data to participate directly in the data entry process. Nevertheless, the invention does not require the originators to change their method of conducting business or rendering services. This can increase a business&#39;s efficiency, boost profitability, and improve data collection accuracy. 
     It is recognized that the quality and integrity of computer data generally can be best assured if the data can be entered at the location and at the time at which the data is gathered. Thus, the originator of the record may determine the existence and assess the value of the data at the time it is recorded. Therefore, preferably, information should be entered into the data recording means at the point of collection by the originator. Nevertheless, that originator may be very busy delivering his or her professional services to the data provider(s). Such originators often do not have time to efficiently enter collected data into a computer system themselves with the apparatus and systems presently available. 
     Nevertheless, originators are generally very concerned about and expend considerable effort to ensure that they document the services that they render. Medical service providers must contend with the additional problem of maintaining control over the distribution of medicines, especially controlled pharmaceuticals and narcotics, and ensuring that improper or dangerous combinations of medicines are not distributed or prescribed. Accurate records, therefore, may have legal importance beyond their importance to patient care. Further, the careful documentation of distributions of medicines and other products is essential to accurate inventory control. 
     Usually, such originators desire &#34;hardcopy&#34; records. The traditional path for data consists of the recording of data by the originator and communicating the data in written or oral form to a data processing staff member. At this data entry point, the data is interpreted and transcribed by a data entry clerk or secretary, who often has little or no professional training in the matters to which the data pertains. Verification of the entered data may be limited to a cursory review by the person entering the data. The originator often only reviews subsequent printed reports or special system inquiries. Consequently, the originator may not have personal control over the interpretation, translation, or initial verification of entered data. Nevertheless, he or she may remain largely responsible for the accuracy and integrity of the data entries. 
     Many data originators may also be intimidated by the keyboards, monitors, and processors of related art computer data entry apparatus and systems, or they are concerned with their legal requirement to record data accurately, or both. They may refuse to reenter the same information, which they have already recorded on paper, into the computer, for fear that the data will be entered incorrectly. The present invention allows the originator to enter data directly into the magnetic or other computer data recording means while the &#34;hardcopy&#34; data entry form is being prepared and, thus, eliminates the second step of having supporting staff enter data. Also, unlike many systems which are designed around the keyboard and monitor, a person unfamiliar with computers does not have to first learn to use a keyboard in order to enter data to the apparatus of this invention. 
     Many attempts have been made to solve the problems stated above, and the attempted solutions that exist today are generally manifested in different models of pen-based computers, as described in U.S. Pat. Nos. Doa et al. 5,049,862; Avakian et al. 4,077,036; and Allen 4,991,091, which are incorporated herein by reference. Nevertheless, current pen-based systems may limit form size. See Felkner et al. U.S. Pat. No. 5,006,699. Limited form size requires the use of numerous sub-screens and menus which can be confusing to untrained data originators. 
     Any interactive data entry apparatus involves entering commands, as well as data. Commands are instructions to the computer which are executed by pressing specific function keys or switches or by typing command codes using an alpha-numeric keyboard. Generally, data may be entered using a keyboard, a stylus, a bar code wand, or an electromagnetic pen, or the like. Data may be stored permanently while commands are usually transitory and control the immediate flow of the program logic. Therefore, any apparatus used for interactive data collection should be capable of accepting these two kinds of entries. Moreover, the same function key preferably can be used to enter different commands. In screen-oriented, pen-based computers or monitor and keyboard-based computers, this dual function capability may be implemented by software. These functions, however, may be varied with the type of data to be entered. The ability to vary functions allows the originator to implement a different functionality based upon the type of data entry form to be used. 
     SUMMARY OF THE INVENTION 
     As noted above, it is an object of this invention that the data originator may simultaneously create a written and magnetic or other computer data record of gathered information. It is a feature of the invention that the originator may have immediate access to review entered data. It is an advantage of the invention that the accuracy and efficiency of data entry is increased. Further, the data provider may benefit from the rapid and accurate recordation and analysis of data. 
     It is another object of this invention that entered data is almost immediately available to the originator for analysis. Another feature of this invention is that the originator may receive rapid feedback and recommendations from or via the apparatus&#39;s processor based on entered data. Moreover, feedback or recommendations may be provided to the originator by aural or visual feedback means. It is an advantage of this invention that because of the interaction between the originator and the apparatus, data gathering may often be more thorough. The originator may even be prompted by the apparatus to explore additional areas based on data already entered, e.g., recognized combinations of medical conditions, such as high blood pressure and diabetes creating a greater danger of retinopathy, or patterns of symptoms, such as shortness of breath and pain in the patient&#39;s left arm indicating a possible heart attack. 
     It is yet another object of the invention to provide an apparatus which even originators that have little or no experience with computers or keyboards will be encouraged to use. It is a feature of this invention that it can be used with numerous forms which are commonly used by various data originators. Thus, there should be little or no &#34;learning curve&#34; because the originators are already familiar with the data entry forms, the steps that are required to complete a given form, and the data requested on the forms. It is a further advantage of this invention that the clipboard-like configuration is familiar to most data originators and data providers. 
     An embodiment of the present invention is a data collection, analysis, and recording apparatus for simultaneously producing a written and a computer record. The apparatus may comprise a data entry form having data entry spaces and a processor for receiving and recording a description of said form and commands for manipulating data collection analysis, and recording. Further, the apparatus may include a digitizer for retrieving the description of the form, for generating a data entry area having data entry locations corresponding to the data entry spaces and command selection locations, and for receiving and recording in the processor, entries made at the data entry locations. A clip is attached to the digitizer, such that the clip holds the form against the data entry area. Thus, the data entry spaces are aligned with the data entry locations. The clip may include a template or an overlay, or both. Moreover, the clip may be movably, e.g., pivotally or slidably, attached to the digitizer. In addition, the apparatus may have a stylus, such as an electromagnetic or magnetic stylus, for selecting the command selection locations and for simultaneously entering data in the data entry spaces and at the data entry locations. Suitable styli may include an ink or graphite cartridge, or the like, and various designs of such styli are known in the art. 
     Another embodiment of the present invention is a data collection, analysis, and storage apparatus for simultaneously producing a written and a magnetic or other computer data record. Although the most universally accepted technology for data recording or memory devices is magnetic recording, other technologies, such as laser recording, may also be suitable. The apparatus may comprise a data entry form having data entry spaces and a processor, such as a microprocessor, for receiving and storing a description of the form and commands for manipulating data collection, analysis, and storage. It may further comprise a digitizer for retrieving the description of the form, for generating a data entry area having data entry locations corresponding to the data entry spaces and command selection locations, and for receiving and storing in the processor entries made at the data entry locations. A clip may be attached, e.g., pivotally attached, to the digitizer, such that the clip can hold the form against the data entry area. When the form is held against the data entry area by the clip, the data entry spaces are aligned with the data entry locations. 
     The clip may comprise an overlay or transparent surface, such that the clip holds the form against the data entry area. A template for identifying the command selection locations may also be mounted on the clip. A moveable clip design permits the use of entire form for originator data entry while maintaining the special functionality of the clip. By implementing the command functions with the clip, it is not necessary to reprint the data entry forms every time the functionalities of the system change. A stylus, e.g. an electromagnetic or magnetic stylus, or the like, may be used for selecting the command selection locations or for simultaneously entering data in the form&#39;s data entry spaces and at the data entry locations. For example, when activated, electromagnetic styli may generate an electromagnetic field in the vicinity of the stylus&#39;s tip, e.g., within a radius of less than about 1 cm of the tip, or electromagnetic energy, e.g., a light beam, may be projected from the tip. Alternatively, when a magnetic stylus is activated, a magnetic field may be generated in the vicinity, e.g., within a radius of less than 1 cm, of the stylus&#39;s tip. Command selection locations may be selected by activating the stylus proximately to the command selection locations. 
     In another embodiment, the apparatus may also comprise at least one memory port for linking the apparatus with external devices, including peripherals and add-on memory cards. Further, the apparatus may include communication ports, such as industry standard parallel and serial communication ports and custom configurable communication ports. Moreover, the apparatus may also comprise an access limiting means, such as an access key and key slot, a coded identification card and card reader, or a circuit for identifying a keyed alpha-numeric access code. This access limiting means prevents unauthorized persons from entering data or from gaining access to stored data via the processor. 
     In yet another embodiment, the apparatus may comprise a display that is pivotally mounted on the digitizer. In the alternative or in addition to the display, the apparatus may include an audio reproduction device. This device may comprise a speaker or speakers, a microphone, and sound recordation means to permit the originator to tailor his or her own audio feedback. The apparatus may also comprise a scroll control for visually or aurally reviewing entered data. 
     The digitizer may be fitted with two or more form orienting posts. The form may have holes therethrough corresponding to the posts for accurately positioning the form on the digitizer. Moreover, optically readable identifying information may also be encoded on the form and the template, so that when the clip is closed, an optical reader for reading and decoding the identifying information and transmitting the information to the digitizer may be activated. 
     In still another embodiment, the apparatus may comprise a central processor and wireless communication means for transferring commands and entered data between the processor and the central processor. This wireless communication means may include means for transmitting and receiving electromagnetic transmissions, such as infrared (LR) or radio frequency (RF) transmitters and receivers. Further, these communication means may include intermediate terminals or modules for relaying commands or data between the processor and the central processor. Moreover, these means may also be used to transfer commands and data between apparatus. 
     Various sets of commands and numerous form descriptions may be received and stored in the processor and in view of the capability of wireless communication between the processor and the central processor, large amounts of storage space and data may be rapidly made available to the originator. The digitizer may also be bit mapped, so that each storage position in the processor may be assigned to a physical location on the digitizer data entry area. The digitizer may further comprise means for recognizing hand-printed characters, such as numerals, letters, and symbols. 
     In another embodiment, the stylus may include a replaceable ink cartridge for entering data in the data entry spaces on the form. The transparent surface prevents ink from the stylus from contacting and fouling the data entry area, command selection locations, or the template, yet allows the stylus to make command selections in the digitizer. A holder for storing the stylus and a cable for securing the stylus to the apparatus and for carrying signals from the stylus to the apparatus may also be included in this embodiment. 
     Other objects, advantages, and features will be apparent when the detailed description of preferred embodiments of the invention and the drawings are considered. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The physical and logical layout of the invention may be best illustrated in the following drawings. 
     FIG. 1 is a front view of an embodiment of the apparatus with the clip in a down position. 
     FIG. 2 is a partial sample data entry form with an optically readable identification code. 
     FIG. 3 is a perspective a view of an embodiment of the apparatus with the clip in the open position. 
     FIG. 4 is a front view of an embodiment of the apparatus with the clip in the up position. 
     FIG. 5 is a sample command template with an optically readable identification code. 
     FIG. 6 is a bottom view of an embodiment of the apparatus depicting various communication ports. 
     FIG. 7 is a front view of an embodiment of the apparatus depicting a self-stick removable note holder in the open position. 
     FIG. 8 is a rear view of an embodiment of the apparatus depicting a data entry form holder bracket. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Preferably, this invention is portable, and a preferred embodiment of the apparatus may be only slightly larger than a standard letter-size paper, e.g., about 81/2×11. To begin operation, the originator must first satisfy a security access means. This is preferably accomplished by inserting a coded identification card into a card reader. Data may be optically or magnetically encoded on the card, and the card may also carry various other identifying information, such as the originator&#39;s identity and the company for which the originator works. It may also carry certain information on the data provider, such as a patient&#39;s medical history. The appropriate mode of operation (on-line or off-line) is then selected. When the off-fine mode is selected, entered data is stored locally in the processor. In the on-line mode, however, the data is transmitted to the central processor. A data entry form, e.g., a medical encounter form, may then be placed, face-up, on the digitizer. The form is aligned using form orienting posts provided on the digitizer and holes present in the form. The clip is used to further hold the form in place. 
     After the form is positioned and the clip is closed, the clip uses a photo-detector army to optically read digitally encoded information from the form. This information may pertain to a variety of aspects of the form, such as the form number and encounter specific function key information. A data entry area mapping the form is then generated on the digitizer, such that the date entry spaces on the overlying data entry form are aligned with data entry locations on the data entry area. Once the form identification number has been decoded, the template identifying the specific command selection locations on that form may be selected and mounted on the clip. 
     The data entry form also may contain a prioritized list of commonly gathered data. Items from this list, such as medical diagnosis or procedures, may be selected by the originator for the efficiency of data entry, and are coded for ease of entry. The originator may then use a computer ballpoint refill pen or a stylus, such as a computer-pen equipped with a replaceable ink cartridge, to enter the desired data items, e.g., services rendered or medicines prescribed to a patient. The pen or stylus can be housed in a molded holder fitted to the digitizer when not in use. As the originator marks the appropriate data entry space on the form, the digitizer identifies the data entry location, stores the entered data, e.g., a check-mark or alpha-numeric character, and generates output in various forms for verification by the originator. 
     This clip further provides command selection locations for the originator to enter commands and alpha-numeric data. The command selection locations are defined by interchangeable templates which may be mounted on the clip. Moreover, entries can be deleted by simply crossing-out an improper entry on the form. Hand-printed, alpha-numeric entries entered into designated spaces may also be recognized by the digitizer and stored in a local processor or sent to the central processor, or both. The apparatus further may assist in the gathering of correct data by guiding the originator thorough complete and logical data entry. 
     The apparatus then verifies the originator&#39;s entries by providing audio or visual feedback, or both. The apparatus may also generate interactive prompts or &#34;questions,&#34; if the local processor or central processor identifies data entered as incomplete, incorrect, or inconsistent. Audio verification is broadcast through a speaker or speakers. The originator may select the author of the prerecorded audio responses, and these responses may be recorded on a microphone in the apparatus. In addition to the audio feedback, visual verification can be accomplished on a video display by reviewing entered data. 
     Referring to FIG. 1, the apparatus 1 may have a digitizer 10 with a surface that is about 81/2 inches by about 11 inches for placement of a preprinted data entry form. See FIG. 2. The form may be positioned properly by two form orienting posts 12 and held in place by a clip 28. Digitizer 10 can employ a wide variety of known digitizer technology, such as capacitively-coupled, electromagnetically coupled, or other digitizing technology, which does not require stylus pressure on the digitizing surface for signal transmission. The output of digitizer 10 may be processed by a local processor, such as a microprocessor, which correctly interprets the entries based on the data entry form. Further, digitizer 10 may have sufficient entry resolution to capture hand-printed entries, such as signatures and phrases and short sentences. The form may include optically readable identification codes, and it may be automatically identified upon closure of clip 28. See FIG. 3. This identification process is described in greater detail below. 
     Apparatus 1 may also contain memory or data recording means to record entered data and commands. Apparatus 1 also may allow downloading of microprocessor instruction codes from a central processor to allow apparatus 1 to be reprogrammed to use new forms and new commands. The memory can be of any common type, including flash memory, which allows downloaded code to be saved even when power is removed from apparatus 1. Apparatus 1 may further contain an access limiting device 34, such as an access key and key slot or a magnetically or optically coded identification card and card reader, to prevent unauthorized use of or access to entered data. 
     When capturing information from a form, the microprocessor may utilize a mapping of potentially active data entry and command selection locations. A stylus 22 with a ball-point pen ink cartridge may be used to enter data to digitizer 10. Stylus 22 also may be an electromagnetic or magnetic stylus and the data entry and command selection locations may include a series of switches reactive to electromagnetic signals, e.g., visible or infrared light, or magnetic fields. Moreover, Stylus 22 may include a combination of an ink cartridge and an electromagnetic energy or magnetic filed generator. Stylus 22 may be attached to apparatus 1 by a cable 24. Stylus 22 may also contain a switch mechanism which is actuated automatically when the stylus tip contacts the template, such as when originator writes on digitizer 10 or manually, such as when the originator may activate a switch, such as a button on the stylus. The switch sends an electronic signal to the microprocessor via cable 24 indicating that a valid entry is being made. Because valid entries may only be received upon activation of this switch, apparatus 1 and the microprocessor can enter a standby mode until such a signal from stylus 22 is received, thus conserving battery power. Further, apparatus 1 may be fitted with a housing 26 for holding or stowing stylus 22 when not in use. 
     Apparatus 1 may also have a display 18 which provides an originator with visual feedback, such as by echoing entered data, updating status, and displaying requested information. Display 18 can display text and characters, or it may produce graphic presentations or icons, and may employ currently known technologies, such as a cathode ray tube (CRT) or a liquid crystal displays (LCD). The information shown on display 18 is controlled by the microprocessor. In addition to feedback of selected entries, display 18 can display entry options to the originator, such as the list of allowed county codes, discussed above. Further, display 18 has a hinge 20 which allows display 18 to be pivoted in order to achieve improved viewing angles and to reduce glare or for ease of transportation. This feature further permits apparatus 1 to be modified to include various sizes and types of display 18 to meet differing originator needs. 
     A scroll control 42 may also be added to apparatus 1 to allow easy selection of desired data from groups of data entries too long to be reviewed on a single screen presentation by display 18. Scroll control 42 located at the bottom of apparatus 1 allows the originator to scroll through the data/menu options. When not being used, scroll control 42 sits in a neutral or centered position. It can be turned left or right using stylus 22. When turned to the left or right, the list or menu is scrolled up or down, respectively. The farther that scroll control 42 is turned from the neutral position, the faster the entries scroll. Additional visual originator feedback is provided by status LEDs 44 or other small visual indicators which can indicate apparatus status, such as whether apparatus 1 is on-line or off-line with the central processor or battery low power indications. 
     Apparatus 1 may also contain wireless communication means, such as an infrared (IR) link or radio frequency (RF) link. Either of these means would be known and understood by a person of ordinary skill in the art and will not be discussed in greater detail herein. In the embodiment depicted in FIG. 1, an IR transmitting port 14 and an IR receiving port 16 are incorporated into form orienting posts 12. This wireless communication capability along with the use of a battery or batteries as a power source permits apparatus 1 to be completely portable and still allows the originator to interact with the central processor. This interaction permits locally entered data to be sent to the central processor for recording and analysis. It also permits the originator to locally access peripheral devices attached to the central processor. Further, communication with other originators who are in communication with the central processor is possible. 
     Electronic photo-emitter/detection unit 38 of clip 28 may also employ known technologies and might comprise light emitters, such as LEDs, generating signals received by discrete photo-diodes or arrays of photo-diodes. Alternatively, a charged coupled device (CCD) sensor army could be used as the photo-detector to read high density optical codes from data entry forms. As will be discussed below, similar optically readable identification codes may also be imprinted on and read from templates, such as template 3 depicted in FIG. 5. Sensors, such as optical sensors, are included which detect clip 28 opening and closing to allow automatic form and template identification by clip 28 closure. Further, the photo-emitters are under the control of the microprocessor, and the data from the photo-receivers is supplied to the microprocessor for decoding and interpretation. The decoded information indicates the type of form being used and allows the microprocessor to align the form&#39;s data entry spaces with data entry locations and, where appropriate, to interpret entries as alpha-numeric characters or hand-printed entries, such as an alpha-numeric code, to be digitized, bit mapped, and recorded. Also, the type of template mounted on clip 28 can be determined, thus, allowing the microprocessor to respond to data or commands entered via clip 28. 
     A sample data entry form is depicted in FIG. 2. Essentially, form 2 comprises lines of text, such as &#34;2. Cells,&#34; 50. Each line of text may be associated with the outline of a data entry space. In this case, a data entry space 52 is a square box to the left of line of text 50. Using stylus 22 to make a mark in space 52 selects that line of text for recordation. The microprocessor having detected this stylus entry accesses its internal map and determines that the originator has accessed the data entry space associated with line of text 50. Therefore, line of text 50 is recorded in the local processor, i.e., the microprocessor, or sent to the central processor, or both. Further, a selected item can be deleted by simply drawing a line through the previously selected line of text. Again, the local processor accesses its internal map to identify and delete the entry, and if necessary, it instructs the central processor to delete the entry as well. 
     As an example of the entry of hand-printed data, an alpha-numeric data entry space near the upper right corner of form 2 labeled &#34;Enter County Code From List&#34; 56 is shown which allows an alpha-numeric code to be written in this space. When such an entry is made the microprocessor accesses its map for this data entry form and processes the entry with a character recognition routine implemented in the microprocessor&#39;s instruction code. The recognized characters then may be stored in the microprocessor or sent to the central processor. The forms may also contain a region for free-form written entries, such as a signature space 54. Entries written in this area may be digitized and recorded for later viewing just as they were entered. 
     Another feature of form 2 is an optically readable identification code 58 printed along the bottom of form 2. As described above, code 58 is used by apparatus 1 to access information about form 2 to be used by the microprocessor in properly interpreting entries. Moreover, additional information for form 2, such as patient information in a medical application, can also be included in this optically encoded information. For convenience to the originator, a form holder 76 may also be located on the rear of the apparatus, as shown in FIG. 8. 
     As can be seen by referring to FIG. 4, clip 28 may be comprised of several individual components. Among these components are photoemitter/detection unit 38 and a transparent surface 30. Also, transparent surface 30 of clip 28 may be configured, so that a template 3, which is depicted in FIG. 5, may be mounted on clip 28. Template 3 identifies alphanumeric function keys 62 associated with form 2. A template optical identification code 66 may be used to identify template 3 for the microprocessor and to allow the microprocessor to determine if the appropriate template has been mounted. A hinge 36 allows clip 28 to be pivoted open, so that forms may be placed upon the digitizer&#39;s surface, and templates may be mounted, as depicted in FIG. 3. It also includes a mechanical means for moving transparent surface 30 of the clip 28 up, so that data may be entered on the lower portions of the data entry form. As indicated by the arrows in FIG. 4, clip 28 may move slidably across the surface of digitizer 10, thereby exposing the lower portions of the data entry form. This allows the entire form to be used for data entry. 
     The signals may be transmitted to digitizer 10 by various means, including pressure exerted on the digitizing surface, by electromagnetic or magnetic fields generated in stylus 22 in proximity to digitizer 10, or by electromagnetic energy projected onto the digitizer surface. The stylus switch is activated, and the electronic signal is sent to the microprocessor to indicate that a valid data entry or command selection is being made. Nevertheless, the stylus&#39;s tip may be prevented from contacting template 3 or digitizer 10 and, therefore, neither template 3 nor digitizer 10 may be fouled with ink from stylus 22. Further, if an electromagnetic or magnetic stylus is used stylus 22 need not contact template 3 or digitizer 10. Stylus 22 may be used to make a data entry or command selection by activating stylus 22 in close proximity to template 3 or digitizer 10, such as within about 1/2 cm of template 3, so that electromagnetic energy may contact or the influence of an electromagnetic or a magnetic field may be felt in digitizer 10. For example, such an electromagnetic or magnetic stylus may be placed directly above the data entry or command selection locations. 
     An example of a template is depicted in FIG. 5. Each command selection location 60 may be associated with an alpha-numeric function key 62 which may be selected by the originator. Function keys 62 may represent a single alpha-numeric character or a word or function. This allows the originator to enter both alpha-numeric text or function commands. Alternatively, template 3 may identify dual purpose toggle keys. These keys allow the originator to shift between two modes of entry or operation. As an example, a toggle key in the lower right-hand corner of template 3 labeled Fkey/Alpha 64 toggles between entry modes. Template optical identification code 66, which is automatically sensed by apparatus 1 when clip 28 closes, may also included on template 3. Means for identifying template 3 are necessary because the commands are application dependent. New commands can be tailored for a particular application by preparing a new template and loading the proper instructions to the microprocessor. 
     As depicted in FIG. 6, apparatus 1 may contain one or more memory ports, such as one or more memory or peripheral card slots 32. Slot 32 may be in an industry standard format, such as a PCMCIA slot. When slot 32 is used for additional memory, memory cards permit extended data acquisition or permit the originator to access information previously downloaded from the central processor. Moreover, slot 32 can be used for peripherals, such as a modem which would permit remote access to the central processor. Additionally, apparatus 1 may contain a plurality of additional communication ports. For example, standard serial communication ports 69, such as RS232 ports, can be included. Serial links would allow communication with apparatus and systems which are not capable of a wireless interface. Also, serial links could be used to allow originators to communicate through external modems. Further, parallel communication ports 68, e.g., IEEE 488 and SCSI ports, or custom configurable communication ports 72 can be included in apparatus 1. Ports 68 could include an industry standard, parallel printer port which would allow the originator to order a printout (at a printer (not shown)) of a summary of entered data directly from apparatus 1. 
     It is also envisioned that apparatus 1 could contain an input port 74 for a bar code wand (not shown) to allow the originator to capture bar coded information from the data entry form. A bar code wand could be especially useful for tracking inventory or, possibly, for dispensing medicine. The bar code reader wand and the memory and communication ports described above may also be controlled by and allow communication with the microprocessor. These ports may be used to rapidly update the commands and the instruction code storm on the microprocessor or to down load data from the microprocessor. 
     Apparatus 1 may also have a local power source, such as internal batteries, which may be used in conjunction with the wireless communication ports to permit completely portable operation. An input port 70, see FIG. 6, from an AC power adaptor can be used to charge the batteries and allow continued operation of apparatus 1 if the batteries are low or removed. 
     To provide audio feedback and allow interactive voice communications, this apparatus can include a speaker or speakers and a microphone. The audio feedback can range from simple clicks as data entry or command selection locations are accessed to spoken feedback echoing entered data or giving instructions. It is envisioned that the amount of audio feedback can be determined by the originator through clip functions. Apparatus 1 may also allow the originator to dictate voice messages which may be captured and recorded at the local processor or sent to the central processor, or both. Apparatus 1 may employ known speech compression technology to allow greater amounts of recording space for speech in available memory and to reduce the bandwidth requirements for sending digitized speech to the central processor. 
     The same bit mapping technique described with respect to FIG. 2 can also be applied to an area of a digitizer 80 onto which a self-stick removable note 84 can be placed. Such notes may be small rectangular sheets of paper presenting one side for recording information and having a strip of weakly binding adhesive along the upper portion of the reverse side, e.g., Post-It™ or Highland™ notes which are manufactured by the 3M Company of St. Paul, Minn. See FIG. 7. This area can cover the normal forms portion of the apparatus and can be toggled as a bit map or standard data form entry area by virtue of a clip function. Bit mapping is a process involving the assignment of each position in a processor&#39;s recording area to a physical location on a display or, in this case, to the digitizer&#39;s data entry area. A command function could activate a predetermined area outlined on digitizer 80. Alternatively, the area could be activated automatically by a sensor attached to the slidable note holding device 82. After capture, removable note 84 can be placed anywhere on form 2, but the entered data would then be recorded as a bit map entry to the data entry form. 
     Although a derailed description of the present invention has been provided above, it is to be understood that the scope of the invention is not to be limited thereby, but is to be determined by the claims which follow.