Hand-held data collection computer terminal having power management architecture including switchable multi-purpose input display screen
A portable data collection terminal has an elongate housing with a hand grip conforming rear surface. A front surface features a numerical keyboard adjacent a lower end of the housing and an LCD screen adjacent the keyboard toward an upper end of the housing. The display screen is of elongate rectangular shape, its length extending longitudinally of the housing of the data terminal. The active area of the display screen is covered by a touch sensitive overlay screen which is configured in one mode of operation of the data terminal into an alphabetical keyboard. The orientation of the display is switchable between orientations in which the line direction of the displayed data extends across or longitudinally of the data terminal. The keys of the numerical keyboard are identified by indicia disposed on a template. The orientation of the template may be sensed to switch the orientation of the displayed data and touch sensitive key identifiers to correspond to the orientation of the indicia on the template. As a further embodiment an electromagnetic activation by a pen may be used to enter data into a data terminal. Power saving shutdown extends the battery life of the data terminal. A shutdown mode permits resumption of operations by depression of a key. During operations power consumption is reduced by efficient distribution of operations control between microprocessors. The microprocessors have shared access to and control of system operations.
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The invention relates generally to data collection and processing systems and more particularly to portable data terminals as operator manipulatable data input and output devices with display and verification of data.
The invention herein is a further improvement of related subject matter contained in the cross-referenced prior patent applications, which prior patent applications are relied upon for priority rights in previously described novel features.
Portable data terminals are generally known components of state of the art business systems. The data terminals may be taken to merchandise storage facilities for inventory control or customer service transactions, or may be used in any one of various other commercial applications to serve as data input or output devices for central data processing and control stations.
Central data processing or control stations are most useful when business data are always current and readily available. Prompt data entry and retrieval at the working level through various operator controlled portable data terminals is recognized as a basis for optimizing, among various business activities, inventory control and customer service activities, business forecasting and marketing operations, to name a just a few.
Increased versatility in data input and output arrangements tends to increase power usage of the portable data terminals, thereby decreasing usage periods between battery exchanges or recharging operations. Touch sensitive or pen actuated data input systems are known. However, in the past, such pen actuated data input systems were generally limited to the use of pens for digitizer boards or in conjunction with full keyboard type computer terminals. While the former devices are considered limited in their application, the latter are comparatively bulky, even as lap top computers, and are not useful for practical data entry and retrieval in shop, warehouse, store or delivery route environments.SUMMARY OF THE INVENTION
The objective of the present invention was early on to expand on the utility of relatively small, portable, hand-held data collection terminals. The invention recognizes a need for greater versatility in hand-held data terminals, thereby improving indirectly on overall usefulness of a business system which uses a number of these data terminals as roaming data input and retrieval devices.
It is therefore an object of the invention to provide an improved compact data input and display device with increased functionality.
It is another object of the invention to arrange an alphanumeric keyboard for multi-orientational use.
Further in accordance herewith it is an object of the invention to provide a pen-activated data input device which interactively may be prompted through display screen prompts.
Another object of the invention is to provide a robust data terminal having a display screen sized to permit operator input via pen strokes and having the capability to change to keyboard entries interchangeably with entry via pen-type signals.
Yet another object of the invention is a power management control function implemented through software controlled microprocessor functions, the power management function including selectively shutting the data terminal down without loss of current data interchange status states on an Input-Output bus (I/O Bus).
A further object of the invention is a power management control function to minimize power consumption of the data terminal during active operation by allocating control and applications tasks between microprocessors according to computational performance and according to power consumption of the respective microprocessors.
It is an additional object of the invention to allow the microprocessors to communicate to one another by mutual sharing of data including a functional arrangement whereby any of the microprocessors can communicate with the device buses
According one aspect of the invention, it is consequently contemplated to increase the data input capacity of a portable data terminal with a touch sensitive liquid crystal display overlay. The touch sensitive display overlay may function as a keyboard or as a provision for entering graphic data such as signatures. Another keyboard may be a numerical keyboard or may be activated as a function key board to supplement a touch sensitive keyboard implemented as an overlay of a display screen.
In a particular embodiment in accordance with the invention, keys of the touch sensitive keyboard of the display screen of the portable data terminal may be selectively reorientable with respect to the data terminal. In accordance with a particular feature of the invention, the keys of key areas of the touch sensitive keyboard are reoriented by switching key assignment areas within the touch sensitive display screen and by reorienting indicia within each of the switched touch sensitive areas of the board to change the orientation of the indicia to correspond to a change in the orientation of the keyboard of the touch sensitive area.
Further in accordance with the invention, a keyboard is disposed adjacent a display screen of a portable data terminal in a frontal face of the data terminal. The keyboard includes an array of keys, each key having an assigned function, and an array of indicia identifying the function of each of the keys of the array. The array of indicia is disposed on a matrix removably attachable to the frontal face of the data terminal. The array of indicia may be removed and replaced by another array of indicia, showing reassigned functions of each of the keys, and the functions of the respective keys are reassigned in accordance with such array of indicia. Alternatively, molded keys may include permanent indicia which display functions inherent to default settings of a data terminal.
Also according to the present invention, a data terminal has a display screen and graphic data input surface coincident with and disposed beneath the display screen. Data input into the graphic data input surface may be obtained either via an electromagnetic pen, also referred to as an active pen, or via a touch sensitive screen via a pointed object, such as a stylus.
Further in accordance herewith, the data terminal includes operation shadowing circuits which include a function of shadowing Input-Output (I/O) device states and a function of storing microprocessor register states during a shutdown procedure. Pursuant to the shadowing and microprocessor register storage, the data terminal may be shut down and reactivated without loss of control or I/O status data and with the ability to complete an operation in progress during the time of shutdown of the data terminal.
Further in accordance herewith, the data terminal includes a dual microprocessor processor arrangement in which applications tasks and activity management and control tasks are efficiently allocated between the two microprocessors. Pursuant to this arrangement power consumption inherent in the routine operation of the data terminal the is minimized, allowing for greater processing power and speeds over a given battery discharge period.
Further in accordance herewith, the data terminal includes a dual microprocessor arrangement in which information processed by one microprocessor is shared with the other microprocessor allowing for shared access to the system buses by either microprocessor. Pursuant to this arrangement control of the entire system may be accomplished by either microprocessor resulting in efficient power management while maintaining standard PC (personal computer) compatibility and flexibility from the vantage of the user and peripheral devices.
Further in accordance herewith, a data terminal includes a shock and weather resistant housing and a keyboard orientation with respect to a display screen which causes an included angle to protect both the keyboard and the display screen from contact with a fiat hard bottom surface during a fall of the data terminal against such surface. Co-molding of shock absorbing material to the surface of the housing distributes impact forces to which the data terminal may be exposed as a result of a fall. In a preferred embodiment, resilient sealing strip interposed between access covers and the housing provide a weather-sealed housing.
In a presently preferred embodiment of the invention, a housing of the data terminal includes top and bottom or base housing shells. The base housing shell is an accessory base and has a central accessory attachment opening. The accessory attachment opening or accessory pod opening may by covered by a removable base cover when no accessory pods are attached. A base cover in accordance herewith is in a shape of a multi-function handgrip or terminal grip and stabilizer. The handgrip comprises a longitudinally centered concave, transversely peaked stabilizer shape with dual, laterally offset, symmetrical handgrip ridges with palmrest indentations for alternatively left and right hand gripping functions. The dual handgrip ridges include co-molded ribbing which also provides impact resistance. The removable base cover may be exchanged for an accessory pod which is centrally disposed, symmetrically with respect to a longitudinal central axis of the housing of the data terminal. The accessory pod has a width transverse to the longitudinal axis which is less than the transverse width of the data terminal, the accessory pod including a handgrip portion by which an operator may hold the data terminal while operating the data terminal.
A handstrap may be attached to upper and lower ends of the base housing shell. The handstrap has a split loop attachment to the lower housing shell. The split loop attachment straddles a docking latch eye disposed on the base housing shell. The docking latch eye engages a latch hook on a dock when the data terminal is inserted into a docking device. Co-molded material disposed on the top housing shell of the data terminal cooperates with the latch eye to retain resilient pressure on the latch hook for retaining surface contacts on the data terminal in contact with mating spring contacts of the docking device while the data terminal remains inserted into the docking device.
Contacts in each of transverse rows of surface contacts disposed at a lower end of the base housing shell are transversely groupwise staggered and longitudinally overlap with the contacts of the other, adjacent group to provide a wider contact surface for engaging spring contacts of a docking device, when the respective data terminal is inserted into a docking receptacle of the docking device. The invention contemplates a single-receptacle docking device and a multi-cavity or multi-receptacle docking device. The data terminal as well as the docking devices feature Ethernet as well as RS-232 or compatible or equivalent LAN (Local Area Network) communications provisions.
The base cover of the data terminal is exchangeable for any of a number of other bases or base pods, each base having a particular one of a number of desirable accessory features. At least one of the base pods is contemplated to include a scanner for reading indicia which may be disposed on a surface external and separate from the data terminal. The scanner may, for example, be a bar code scanner, An operator may insert fingers or a portion of the hand between the housing and one of the handstrap provisions to retain the unit by friction between the hand and the strap.
Various other features and advantages of the invention will become apparent when the detailed description below is read in reference to the appended drawing.BRIEF DESCRIPTION OF THE DRAWINGS
The detailed description refers numerically to elements shown in the drawing wherein:
FIG. 1 shows a pictorial frontal view of a data terminal showing a top shell of a housing with a touch sensitive display screen in combination with a keyboard in accordance with an embodiment of the present invention;
FIG. 2 shows a pictorial view of an underside of the data terminal shown in FIG. 1, showing a bottom or base shell of the housing of the data terminal, and showing a handstrap and various other features of the present invention;
FIG. 3 shows the data terminal shown in FIGS. 1 and 2, and showing further an accessory pod in place of a combination handgrip base plate;
FIG. 4 is a pictorial presentation of a docking device with a docking cavity for receiving and removably retaining the data terminal shown in FIGS. 1, 2 and 3 during storage, data transfer or battery charging operations;
FIG. 5 is a partial, pictorial view of the data terminal shown in FIGS. 1, 2 and 3, showing a lower end of the base shell of the housing of the data terminal in greater detail;
FIG. 6 is a schematically simplified partial view of the data terminal showing the lower end of the base shell of the data terminal of FIGS. 1, 2, and 3, and illustrating particularly an offset of one row of surface contacts with respect to a second row;
FIG. 7 is a schematic representation of a mold to illustrate a first step in a co-molding process;
FIG. 8 is a schematic representation of a mold to illustrate a second step in a co-molding process;
FIG. 9 is a pictorial representation of a multi-cavity docking device for data terminals in accordance with the invention;
FIG. 10 is a simplified pictorial representation of the docking device shown in FIG. 9, showing an, underside of the docking device with a cable connector recess in a housing of the docking device;
FIG. 11 is a composite pictorial representation of the inside of the base shell of the housing of the data terminal depicted in FIGS. 1, 2, and 3, showing major structural elements which are included in a base shell assembly and illustrating further a preferred assembly with selected hardware of the base shell assembly;
FIG. 12 is a composite pictorial representation of the base shell of the housing and such components as shown in FIG. 11, yet viewing the external surface of the base housing shell and showing the related components in a correspondingly oriented view;
FIG. 13 is a composite pictorial representation of the interior of the upper housing shell of the data terminal depicted in FIGS. 1, 2 and 3, showing components that become assembled to the upper shell of the housing of the data terminal in accordance herewith;
FIG. 14 is a composite pictorial representation or exploded view of the data terminal depicted in FIGS. 1, 2, and 3, illustrating an assembly of the base shell assembly to the top shell assembly, and showing further components of the respective data terminal including a PCMCIA memory card and memory card cavity and battery cavity covers;
FIG. 15 is a composite pictorial representation of the memory card cavity cover, showing the interior surface of the cover in greater detail and showing elements of a door latch;
FIG. 16 is a composite pictorial representation of the memory card cavity cover as in FIG. 15, but showing an exterior surface of the cover or door;
FIGS. 17 shows a composite pictorial view of the upper end of the data terminal shown in FIGS. 1, 2, and 3 showing battery and memory card cavities open and showing simplified the shape of a battery about to be inserted into the battery cavity;
FIG. 18 shows a pictorial view of a handstrap which may be attached to the data terminal as shown in FIG. 2;
FIG. 19 shows a pictorial view of a handstrap which may be attached to the data terminal in lieu of the handstrap shown in FIG. 18, the handstrap showing a accessory pod straddling configuration;
FIG. 20 is a diagram of electronic circuits or functions which operate the data terminal in accordance with an embodiment of the invention;
FIG. 21 is a diagram of electronic functions of an input-output function board which may be coupled to an input-output function connector shown in FIG. 20, for example;
FIG. 22 is a control logic flow diagram of a sequence to be followed during power up or power down operations of a data terminal according to the invention;
FIG. 23 is a diagram of electronic functions of a communications interface circuit block shown in FIG. 20;
FIG. 24 is a diagram of electronic routing within a control processor master mode circuit function of the communications interface circuit block depicted in FIG. 23;
FIG. 25 is a sequencing diagram of functions executed by the control processor operating in the control process master mode upon its initiation through the communications interface circuit block;
FIG. 26 is a block diagram showing a routing of address codes within the data terminal upon a completed setup via the control processor master mode function.
FIG. 27 is a diagram of electronic circuits or functions which operate the data terminal in accordance with a second embodiment of the invention;
FIG. 28 is a block diagram of the Power Supply system of the data terminal showing battery cell inputs and power supply output lines;
FIG. 29 is an illustration of an alternative embodiment of the data terminal with a larger sized video display; and
FIG. 30 is an illustration of an alternative embodiment of the data terminal with a smaller sized video display.DETAILED DESCRIPTION
Description of FIGS. 1-3
FIG. 1 shows a portable data collection terminal or data terminal which is designated generally by the numeral 10. The data collection terminal 10 is a handheld, portable unit, which is understood in the art as being powered by a self-contained power source. Such a portable data terminal 10 may operate in what is referred to as a batch mode in which data are collected by, and stored within, the data terminal 10 to be transferred to an alternate data processing unit or host computer (not shown) in a comprehensive "batch" type data transfer operation. In the alternative, the data terminal 10 may be in communication with such a host computer in an interactive or on-line mode via a data communications link, such as a radio frequency transceiver arrangement or a cable-type communications connection.
The data terminal 10, as described herein and as viewed from above, has an elongate, generally rectangularly shaped housing 12. The elongate housing 12, preferably of a high-impact-strength plastic material, encases the data terminal 10. Various types of moldable high-impact-strength plastic materials are known and are generally available. The pictorial representation of the data terminal 10 in FIG. 1 depicts prominently a frontal shell or top shell 14 of the housing 12. A display screen 15 and a keyboard 16 are located, respectively, in an upper end portion 17 and a lower end portion 18 adjacent an upper end 19 and a lower end 20 of the housing 12.
The display screen 15 is preferably a state of the art liquid crystal display screen ("IILCD screen"). State of the art LCD screens generally employ "double super twist" technology. This type of screen is found to provide satisfactory viewing contrast under most direct lighting conditions. It is further possible and desirable to provide backlighting for LCD screens. Power considerations relating to the portability of the data terminal 10 may require a selective disablement or the ability to turn off a backlighting feature.
As is apparent from FIG. 1, the LCD screen 15 is of a comparatively large size, occupying the upper end portion 17 of the frontal face of the top shell 14 except for longitudinal left and right boundary regions 21 and 22 respectively which are molded gripping regions. Each of the gripping regions 21 and 22 features a longitudinal, sculptured finger grip indentation 23 which extends longitudinally in parallel with left and right hand longitudinal edges 24 and 25 of the screen 15. The keyboard 16, being limited in size by the available area on the frontal shell 14, functions primarily as a "numerical" keyboard. However, cursor manipulation and menu based prompts facilitate a variety of dedicated alpha-numeric information entry and retrieval.
The screen 15 has a rectangular, dot addressable display area 26 of 320 (in width) by 480 (in length) pixels which are controlled to operate in a standard VGA display format with 16 gray scales. The referred to backlighting is automatically temperature compensated to adjust for differences in luminescence over an expected range of temperatures. At present, an operating range of -4 to +122 degrees Fahrenheit is contemplated.
The keyboard 16 is in the preferred embodiment a numeric 21-key tactile keyboard. Keys 27 generally are color coded according to functions to set out and aid in distinguish between various functions. In addition, four cursor keys are arranged in a direction-coordinated cluster 28. When the cursor keys are used to manipulate various alpha-numeric menu displays and prompts, the numeric keyboard in conjunction with text prompts appearing on the screen can direct an operator in little time through complex inventory or order taking problems. Data entry is further enhanced by a code reader or laser scanner 29 which may be disposed in an accessory pod 30 (as illustrated in FIG. 3, for example), or a comparable scanner may be coupled through a communications I/O port, as will become apparent from the overall description of the data terminal 10.
Data entry is further enhanced by a touch sensitive active screen area 32 which is provided as an overlay to extend over the entire area of the LCD screen 15. The touch sensitive active surface area 32 may be implemented in a currently preferred manner, for example, either through capacitive or resistive switching and sampling techniques to determine coordinates of a point on the surface area 32 against which a contact pressure is exerted. The overlay area 32 is essentially transparent, such that information displayed on the screen 15 remains clearly discernible. The touch sensitive area is, in the preferred embodiment, activated by a passive pen or stylus which may be used to contact a single or a sequence of definable area locations to delineate pen-written data or information. The intelligent contents of information entered via stylus may be interpreted by software contained within the data terminal 10. Such software may include graphics programs or may include OCS programs for character recognition. It would be possible, for example, that the touch sensitive active area 32 be selectively configured as a keyboard for manual input of alphabetical or special characters. As a further advantageous alternative, software may provide only part of the entire display screen 15 with special keys to be touch-activated by such a data input stylus. In a special case, data prompts may be scrolled up or down on the screen 15 and may-be activated in the alternative by cursor positioning and depression of one of the keys 27 to indicate that the selection has been chosen, or by being touched with the stylus to indicate a corresponding selection. Stylus clips 33 and 34 provide in combination with a recessed stylus cavity a recessed stylus holder 35 at the lower end of the data terminal 10.
FIG. 1 further shows a parting line 36 which extends peripherally about the housing 12 of the data terminal 10. The parting line 36 constitutes a lower boundary of the top or frontal shell 14 and an upper boundary of a bottom or base shell 37 of the housing 12. An assembly of the data terminal 10 is facilitated by upper and lower subassemblies 38 and 39 which are disposed in the upper housing shell 14 and the lower housing shell 37, respectively.
FIG. 2 shows the data terminal from its underside, showing prominently the base shell 37 of the housing 12. The pictorial view of the data terminal 10 shown in FIG. 2 also shows the upper end 19 of the housing 12. As can be seen, the parting line 36 between the frontal shell 14 and the base shell 37 of the housing 12 is not continuous across the upper end 19 of the housing 12. Instead, the upper end 19 shows a battery door 41 and a memory card door 42 both of which provide access to respective parts of the data terminal 10. The doors 41 and 42 are individually removable, such that access may be gained through either without opening the other. Each of the doors 41 and 42 features a quarter-turn quick release lock assembly 43. In the preferred embodiment, the quick release lock assemblies 43 are identical to each other, even though the battery door 41 is somewhat shorter than the memory card door 42, as can be ascertained from FIG. 2. A major body portion of the bottom shell 37 features a continuation of evenly spaced transverse grooves 44 in the lateral gripping regions 21 and 22 of the frontal shell 14 (see FIG. 1). The transversely arranged grooves 44 may be looked upon as being ornamental, but the grooves also enhance the roughness of the respective housing shells, thereby providing a better grip adhesion, to decrease a risk that the data terminal 10 accidentally slips from the grip hands of an operator. Alternatively, the grooves 44 could be ridges. However, the grooves 44 are preferred and readily molded than such ridges. The regions of both the upper and lower ends 19 and 20 show smoothly textured surfaces which are comparatively more resilient, impact shock absorbing rubber moldings. The doors 41 and 42 feature a rounded ridge 46 which continues transversely adjacent the upper end 19 all around the housing 12. Similarly impact resistant, resilient shock protective regions 47 and 48 of the base shell 37 and a corresponding shock protective region 49 of the frontal shell 14 offer protective shielding to the lower end 20 of the data terminal 20. In brief reference to FIGS. 1 and 2, it is to be noted that the upper end portion 17 is disposed at an angle of about seven degrees with respect to the lower end portion 18. The deviation of the two portions from a coextensive longitudinal direction serves both better operator access to both the LCD screen and the keyboard 16, and the included angle between the two tends to position the LCD screen 15 away from damaging contact should the data terminal 10 fall with the screen 15 facing down.
FIG. 2 shows centrally disposed on an underside 51 of the base shell 37 a removable base cover or grip plate 52. The grip plate 52 is sculptured symmetrically about a central, longitudinal plane (shown as centerline 53 in FIG. 6). The plane of symmetry should be visualized as cutting perpendicularly through the center of the housing 12 and through the upper and lower ends 19 and 20. A central portion 54 of the grip plate 52 is concavely formed or inwardly curved with respect to such central plane, the indented portion 54 forming a central, rounded channel 54 which slopes gradually at an angle in a direction of the upper end 19 away from the display screen 15. The sculptured form of the grip plate blends, on left and right sides 56 and 57 of the data terminal, toward the underside 51 of the base shell 37, forming left and right ridges 58 and 59. A sloped head surface 61 extending transversely to the longitudinal extent of the housing 12 forms a third, transverse ridge 62 adjacent the upper end 19 of the housing 12. Resilient, molded left and right rubber gripping pads 63 and 64 feature a pattern of soft, parallel molded ribs to make the ridges 58 and 59 more slip resistant.
The described, multi-ridged, sculptured grip plate 52 provides for various positions in which an operator may hold or support the data terminal 10. The positions are best described in reference to FIGS. 1 and 2. In a first support position the data terminal 10 may rest on an operator's upper leg adjacent the knee while the operator is seated. The longitudinally sloping concave channel 54 has the effect of tilting the display screen toward the operator, providing an improved viewing angle of the display screen 15. The concave channel 54 conforms generally to the shape of the leg.
In another position the data terminal may rest in an operator's hand, with the operator's thumb resting in the sculptured finger grip indentation 23 and pointing toward the upper end 19 of the housing 12. The operator's hand grips the terminal around the adjacent side of the housing 12, either the left side 56 or the right side 57, depending on whether the left or right hand is holding the data terminal 10. Either three or four fingers grip the respective resilient gripping pad 63 or 64, the index finger possibly gripping an upper edge 67 of the grip plate 52, or, alternatively, resting in a forward gripping indent 68 of the respective gripping pads 63 or 64.
In yet another supported operating position of the data terminal 10, the operator's hand may be positioned, palm up, across the underside 51 of the base shell 37, the operator's thumb resting along the respective gripping pad 63 or 64. The operator's fingers grip the respective left or right side 56 or 57 of the housing, with the finger tips resting in the respective finger grip indentation 23 adjacent the display screen 15. The latter cross grasping hold on the data terminal also may take advantage of a handstrap 70 which may be attached to the underside 51 of the base shell 37 to extend longitudinally from adjacent the upper end 19 to adjacent the lower end 20 of the housing 12.
The handstrap 70 shown in FIG. 2 has a transverse upper attachment end 71 with two transverse attachment points 72 adjacent the upper end 19. The attachment end 71 may be screwed, buttoned, clasped or otherwise attached to the underside 51 of the base shell 37. A strap loop 73 of the attachment end 71 holds a strap ring 74 through which a strap 76 may be looped. The strap 76 terminates adjacent the lower end 20 in a bifurcated or forked strap loop 77 which is attached through a holder bracket 78 to the underside of the base shell 37. The holder bracket 78 quickly may be fastened to the underside 51 by two screws 79 or equivalent fasteners and similarly removed for replacement or removal of the strap loop 77. When the strap 76 is looped through the ring 74 it may be attached to itself via convenient hook and loop fasteners in strap regions 83 and 84, a predetermined length of the fastening area 84 providing for adjustment of the effective length and tightness of the handstrap 70. A hand pad 85 is contemplated to provide padding for an operator's hand inserted between the handstrap 70 and the grip plate 52 in the manner described.
The left and right ridges 58 and 59 together with the underside 51 of the base shell adjacent the lower end 20 of the housing 12 further form a rather stable pedestal for supporting the data terminal 10 against a flat surface of a table, for example. In the latter supported position, the angular shape of the ridges with respect to the display screen 15 places the display screen at a tilted position toward the operator.
FIG. 3 is another view of the data terminal 10. In particular, the underside 51 of the base shell 37 of the housing 12 is shown with the already described combination handgrip base plate or grip plate 52 (see FIG. 2) removed, and with the accessory pod 30 attached in its place. Both the grip plate and the accessory pod 30 use common attachment points 91 through which the respective accessory pod 30 or grip plate 52 is screwed as a rectangular cover plate 92 to the underside 51 of the base shell 37 to cover a base shell accessory opening 93 (see FIG. 11) through which one or more of various available accessories may become attached to the data terminal 10 as heretofore described.
The accessory pod 30 shows in particular the scanner 29 disposed behind a scanning window 94, by which bar code symbols may be scanned. The accessory pod 30 may further contain a radio frequency transceiver 96 either in place of the code scanner or reader 29 or in combination therewith. When the radio transceiver 96 is incorporated into the accessory pod 30 of the data terminal 10 in combination with the scanner 29, a planar antenna 97 may be placed peripherally about the scanning window 94, or it may, for example, be molded into a plastic housing 98 which forms the outer configuration of the accessory pod 30 shown in FIG. 3.
Laterally disposed on the accessory pod 30 are left and right scanner trigger buttons 101, only the one on the right side being visible in FIG. 3, by which an operator may trigger the operation of the scanner 29 while pointing the data terminal 10 with the upper end 19 longitudinally in the direction of the codes or information to be read.
The data terminal 10 is shown in FIG. 3 without a handstrap, the transverse attachment points 72 are consequently not used and the holder bracket 78 is mounted to the underside 51 without retaining the strap holder 77. Both FIGS. 2 and 3 show a surface contact assembly 105 disposed centered at the lower end 20 of the housing. The surface contact assembly is an arrangement of a plurality of surface contacts 106 which are preferably arranged in two laterally offset rows of the surface contacts 106, such that one of the contacts 106 in one row is preferably centered on a gap between two contacts in the second row. This type of arrangement has been found to allow access to a greater number of electrical connections within a comparatively small surface area of the surface contact assembly 105.
II. Description of FIGS. 4-6
FIG. 4 in combination with FIGS. 5 and 6 illustrates best the use of the surface contacts in conjunction with a docking device which is designated generally by the numeral 110. The docking device 110 has a housing 111 within which there is a single docking cavity 112. The docking cavity 112 has a width between opposite left and right hand side walls 113 and 114 to accept the width of the lower end 20 of the data terminal 10. When the data terminal is inserted into the cavity 112, opposite left and right hand lower sides 116 and 117 of the data terminal fit between the respective left and right hand side walls 113 and 114. Upon insertion of the data terminal 10 in the docking device 110, the left hand lower side 116 of the data terminal 10 rests in sliding contact against the left hand side wall 113, and the right hand lower side 117 is disposed correspondingly next to the right hand side wall 114 of the cavity 112.
Centered in a back wall 121 of the cavity 112 there is disposed a spring contact assembly 122 which shows a plurality of spring contacts 123 which are grouped in upper and lower contact rows 124 and 125, respectively. Upon insertion of the lower end 20 of the data terminal 10 into the docking cavity 112 of the docking device 110, the spring contacts 123 in the upper row 124 engage with corresponding ones of the surface contacts 106 in an upper row 127 of the surface contact assembly 105. The surface contacts 106 disposed in a lower row 128 of the surface contact assembly 105 correspondingly make contact with the spring contacts 123 in the lower row 125 of spring contacts in the docking device 110. Also, ridges 129 separate adjacent ones of the surface contacts 123 in each contact row. Thus, when the data terminal 10 is inserted into the docking cavity 112, the spring contacts 123 of the upper row 124 ride over the ridges 129 of the lower row 128 of surface contacts 106 minimizing the risk of contact with other than designated surface contacts and spring contacts.
A ledge 132 within the docking cavity 112 shown in FIG. 4 corresponds to an offset 130 (see FIG. 6) in the molded shape of the lower end 20 of the housing 12. The stylus clips 33 and 34 are of course not of the resilient and readily deformable shock protecting rubber material as the molded regions 47, 48 and 49, of the housing 12, for example. Thus, two ejector bars 133 and 134 may be activated to move upward against those rigid housing portions at the respective locations of the stylus clips 33 and 34. The ejector bars 133 and 134 are coupled via a lever linkage (not shown) in a conventional manner to a pushbutton 135, such that a downward push on the pushbutton 135 would cause an upward movement of the ejector bars 133 and 134 to raise the data terminal 10 upward within the docking cavity 112.
Again in reference to FIGS. 4, 5 and 6, above a ledge 137 formed by an assembly block 138 for the spring contacts 123, a retainer bracket 138 has a retainer prong 139 which extends upward. The retainer prong is disposed to fit within a central recess 140 that is formed by the holder bracket 78. The engagement of the retainer prong 139 with the recess 140 of the holder bracket 78 retains the underside 51 of the base shell 37 positioned to retain the spring contacts 123 of the docking device 110 in contact with the surface contacts 106 to minimize any risk of contact bounce between the two when the docking device 110 is used in a vibration prone environment, such as a vehicle, for example.
In reference to FIGS. 3 and 4, an advantageous cooperative use of the resilient shock absorbing molded material regions 49 on the frontal housing shell 14 can be explained. When the data terminal 10 is inserted into the docking device 110 and an operator urges the data terminal 10 toward the back wall 121 to capture the retainer prong 139 in the recess 140 behind the holder bracket 78, the lower end 20 of the housing 12 of the data terminal 10 is urged away from the back wall 121 of the docking cavity 112 by the combined spring force exerted by the spring contacts 123. The spring force urges the lower end 20 toward and against front cavity ledges 142 and 143. The molded resilient material of the top shell regions 49 resiliently contact the inner surfaces of the ledges 142 and 143. This causes the retainer prong 139 to be resiliently urged outward against the holder bracket 78. The resilient retaining force between the spring contacts and the resilient material in the regions 49 generates a friction hold of the resilient material 49 against the respective ledges 142 and 143. As a result, though simple in the approach, the inserted data terminal 10 is retained in the docking cavity with a measurable retaining force as a result of some compression of the resilient material 49 against the ledges 142 and 143. The retaining force secures the data terminal 10 within the docking cavity even though the docking cavity only extends upward along the housing 12 to terminate substantially at the holder bracket 78. One resulting advantage is that the docking device 110 does not interfere with either the grip plate 52 or with a more protruding accessory pod 30 that may be attached to the data terminal 10. The lateral ledges 142 and 143 are complemented in their resilient holding function by a transverse ledge 144. However, the three ledges 142, 143 and 144 engage only the peripherally disposed resiliently molded portions of the frontal shell 14 at the lower end of the housing, leaving exposed the keyboard when the data terminal 10 is retained within the docking device 10. Also, the engagement between the spring contacts 123 in the docking device 110 and the surface contacts 106 of the data terminal 10 remains bounce resistant while the data terminal 10 is retained in the docking device. The engagement between the contacts 106 and 123 is used to couple both power and system communication to the data terminal 10. Thus, on a reverse side of the docking device (not shown) typical power and communications connectors may couple the docking device, for example, to RS 232, RS 485, Ethernet local area network (LAN) hard wired cables, and also provide proper external power to operate the data terminal 10 and to recharge its internal batteries during docking periods. The plurality of spring contacts 123 schematically simplified represent such typical communications and power connections.
From the above description of a friction type retention mechanism for holding the data terminal 10 within the docking device or station 110 depicted in FIG. 4, in further reference to FIG. 5, the significance of the bifurcated strap holder 77 becomes more apparent. The attachment of the strap 76 through to the holder bracket 78 is convenient. However, the just described second function of the holder bracket 78, namely to contribute to the secure engagement of the spring contacts 123 with the surface contacts 106, and to contribute to the retention of the data terminal 10 in the docking device 110 is of yet greater significance. The bifurcated strap holder 77 satisfies all conditions without interference with the docking procedures.
III. Description of FIGS. 7-8
As already described in related prior applications, the resilient regions including the material 49 may be integrated into the shape of the housing 12 in a co-molding process. The term "co-molding", as used herein, refers to a known manufacturing process wherein a part, such as the base shell 37 is first molded, for example, in an injection molding process. In reference to FIGS. 7 and 8, FIG. 7 depicts a simplified cross-sectional view of a first mold 151. An upper mold part 152 is closed against a lower mold part 153, and a thermoplastic molding material is injected. The injected material cools and hardens to form, for example, a part 154 in complementary upper and lower molding cavities 155 and 156 of the respective upper and lower molds 152 and 153.
Referring to FIG. 8, the molded part 154 is thereafter inserted into an second mold 157 which has molding cavities 158 and 159 in upper and lower mold shells 160 and 161, respectively. The cavities 158 and 159 are larger and of altered shape when compared to the first cavities 155 and 156. The molding cavities 158 and 159 not only receive the already molded part 154, but also allow space for the injection of a second molding material, as, for example, thermoplastic rubber material 162. The molded part 154 is disposed within the second mold 157 to form with its outer surface 163 one boundary surface of the space into which the thermoplastic rubber 162 will be injected. Heat energy from the injected hot rubber material 162 tends to plasticize the outer surface 163 of the already molded part 154 to form a somewhat homogeneously linked boundary region along the surface 163 of the molded part 154. The boundary region conforming with the surface 163 has been found to yield a strong bond between the two molded materials or parts 154 and 162. The bond is essentially leak proof. The co-molding process appears therefore ideal for forming various parts such as the described housing shells 14 and 37 with a combination of rigid structural portions with impact resistance and resiliently yielding elements for shock absorbing or sealing functions. The bond appears also not to be confined to a planar surface along the original surface 229. Instead the boundary surface 229 appears converted into a boundary region 163 having a depth along the original surface 163. The region 163 tends to permit a greater dispersion of shear forces. As a result, impact forces tend to become more evenly distributed and dispersed across the surface of the underlying co-molded parts, such as the top and base housing shells 14 and 371, when compared with a typical surface-adhered shock absorbing material.
IV. Description of FIGS. 9-10
FIGS. 9 and 10 depict a multi-cavity docking station 165 which features, as a preferred example, four identical docking cavities 112, essentially the same as the single docking cavity 112 of the docking device 110 as described with respect to FIG. 4. The cavities 112 are also defined within the bounds of the opposite side walls 113 and 114, the back wall 121 and the forward ledges 142, 143 and 144. The communicative engagement and retention of one or more of the data terminals 10 in respectively one or more of the four docking cavities proceeds as described with respect to FIG. 4. FIG. 10 shows an underside of the docking station 165 with a formed recess in the underside to facilitate cabling connections. The multiple-cavity docking station 165 may provide, for example, multiple communications links, such as four Ethernet LAN connectors 166 that are coupled to corresponding ones of the spring contacts 123 in the respective four docking cavities 112. A serial connector 167 and power connectors 168 provide communications and power to each of the docking cavities 112.
V. Description of FIGS. 11-19
FIG. 11 shows a composite pictorial representation of the base shell 37 of the housing 12, and of major components that are assembled to the base shell 37 as a subassembly 173 of the data terminal 10. Looking into the base shell 37, an interior molded wall 174 divides the interior of the base shell 37 into a circuit board cavity 175 and into a battery cavity 176. The base shell accessory opening 93 is centered within the base 37 and extends partly over the battery cavity 176. However, the wall 174 is rounded toward the battery cavity 176 and closes off access through the accessory opening 93 to the battery cavity 176. An input-output circuit board assembly 177 (I/O board assembly 177) is placed into the circuit board cavity 175 and pushed toward the lower end 20 of the base shell 37. A communications connector 178 becomes aligned with and is pushed through a corresponding connector aperture 179 at the lower end 20 of the base shell 37. A rubber seal 180 becomes interposed between the inner surface of the base shell 37 and the connector mounting flange 181 to provide a weather resistant sea peripherally about the connector aperture 179. Once the I/O board 177 is moved forward to extend the communications connector 178 through the aperture 179, the I/O board is aligned with mounting bosses or standoffs 182 and is fastened in position using assembly screws 183. The communications connector 178 is also fastened with two screws 184 to the base shell 37.
The I/O board 177 is of generally rectangular configuration, except for a lateral board extension 185 which supports battery contacts 186. When the I/O board is placed as described, the lateral board extension is disposed at the lower end of the battery cavity 176. A battery stop shim 187 is used between the base shell 37 and the lateral board extension 185 to support the lateral board extension.
Mounted to an upper surface 188 of the I/O board is a PCMCIA connector 189. In a preferred embodiment the PCMCIA connector 189 is of a double-slotted card connector capable of receiving two type II PCMCIA memory cards. First and second vertically layered guide tracks 191 and 192 receive first and second memory cards, respectively. A first card release button 193 and a second card release button 194 extend outward toward the upper end 19 of the housing 12. The release buttons 193 and 194 are accessible from the upper end of the housing 12 to selectively release a card from either one of the guide tracks 191 or 192 by a push of the respective release button. After assembly of the I/O board assembly 177 into the base shell 37, other components shown in FIG. 11 below the base shell 37 are assembled from or to the exterior of the base shell 37. A resilient pad or label 196 may be placed on the underside of the I/O board assembly 177 aligned with a site of a backup battery holder 197. The backup battery holder is pushed into place on the underside of the I/O board assembly 177. A 9-volt battery 198 serves as backup battery for the data terminal 10. The backup battery 198 is connected to a connector terminal on the I/O board assembly 177 via a connector and power strap 199. A resilient gasket 205, coated with a contact adhesive is placed about the periphery of the base shell accessory opening 93. The annular outline of the gasket 205 indicates comparatively the outline of the accessory opening 93 which is otherwise partly concealed in the pictorial view of FIG. 11.
The surface contact assembly 105 includes on its underside a flexible ribbon cable 206 which is coupled at one end to the surface contacts 106 and at the other end to a ribbon cable pin connector 207. Assembly of the surface contact 105 necessitates a 180 degree turn of the assembly 105 in a horizontal plane and the insertion of the ribbon cable connector 207 through a respective surface contact mounting opening 208 (see FIG. 12) in the base shell 37. A resilient gasket 209 is first placed about such opening 208, such that the ribbon cable 206 extends through an opening 210 in the gasket as well as through the opening 208 in the base shell 37. The ribbon connector 207 is subsequently coupled to a mating connector socket on the I/0 board assembly 177. The surface contact assembly is fastened to the underside of the base shell 37 by two screws 211. Each of the stylus clips 33, 34 is attached to the underside of the base shell 37 at its lower end 20 by a single screw 212 inserted through the respective stylus clip via an oversize access aperture 213. A respective, inner comer formed in the base shell 37 as a seat for the stylus clips 33, 34 assures seating of the clips without rotation. An underside of the holder bracket 78 shows molded ridges 214 which delineate the lateral boundaries of the recess 140 and maintain separation of the bifurcated strap holder 77, thereby retaining the recess 140 clear to accept the prong 139 as described above with respect to FIG. 4. The holder bracket is attached to the underside of the base shell 37 by two screws 79. The component identified by the numeral 211 is a label or model identification plate 215 which is routinely attached to the underside of the base shell 37. An I/O connector 217 mates with an I/O connector strip 218 on a main logic board 219 shown in FIG. 13.
FIG. 12 is a pictorial composite drawing of the components described in reference to FIG. 11, further depicting the undersides of the respective components including that of the base shell 37.
The access opening 93 is defined by a peripheral locator ridge 221, and the sealing gasket 205 is placed peripherally just outside of the locator ridge 221. A curved continuation of the cavity divider wall 174 provides a smooth insertion surface for an elongate battery to be inserted into the battery cavity 176. It is also to be noted that there are shown a combination of three battery contact elements as the battery contacts 186. A third battery contact element may be used in accordance herewith as a battery control contact element 222 for sensing the temperature of a rechargeable battery during recharging operations.
FIG. 13 is a pictorial composite drawing of the frontal or upper housing shell 14, showing the housing shell 14 as viewed from above, looking at an interior or shallow cavity 226 of the upper housing shell 14. A major portion adjacent the upper end 19 of the housing 12 is taken up by a display screen area 227 which is an opening 227 in the upper housing shell 14. A peripheral seal 228 is located and adhesively attached to the inside of the upper housing shell 14 peripherally about the screen area opening 227. A touch sensitive screen 229 having a touch sensitive screen area is aligned with and assembled to the screen area opening 227. Since the touch sensitive area is responsive to the touch of a stylus, the sensing area remains exteriorly exposed within the screen area opening 227 after full assembly of the data terminal 10. An LCD screen assembly 232 including a backing board and LCD address logic is aligned with and assembled to a locating frame 233 such that circuit devices facing the locating frame become aligned with respective device cavities 234, 235 or 236 in the locating frame 233, as an example. The locating frame 233 is aligned with the main logic board 219. An electroluminescent panel 239 (EL panel 239) is placed between the main logic board 219 and the locating frame 233 just prior to the assembly of the locating frame 233, the LCD screen assembly 232 and the EL panel 239 to the main logic board 219. The assembled elements are combined into a single larger subassembly by becoming sandwiched between the main logic board 219 and the locating frame 233 when the main logic board 219 is fastened to the locating frame 233 with screws 240. A memory module 242 is plugged into a memory connector 243 and held to the main logic board 219 by one or more screws 244 or equivalent fasteners.
A sound transmissive, adhesively coated weather seal 246 is located and attached over a buzzer or speaker grid opening 247 disposed in the upper shell 14 adjacent the screen opening 227. A buzzer 249, which could be a miniature speaker, is mounted to the main logic board 219. When the assembled unit of the main logic board 219 and the locating frame 233 is positioned and fastened into the upper shell 14, the buzzer 249 becomes aligned with and located directly adjacent the weather seal 246 and the buzzer grid opening 247.
A key array 251 of keys 27 and a cursor key cluster 28 is placed into respective key openings 252 and 253 in the upper shell 14. A cursor contact spacer 254 is placed over the cursor key cluster 28. A weather seal 255 peripherally seals the interior of the upper housing shell 14 against moisture or environmental contamination. A key contact board 256 with respective key contacts cooperatively acting in response to a depression of one of the keys 27 or the cursor keys is disposed adjacent the key array 251 and is fastened to the interior of the upper shell 14 with screws 257. A key template 258 becomes adhesively attached to the exterior surface of the upper housing shell 14 adjacent the lower end 20. The key template 258 may be a decorative addition to the exterior of the housing 12, or the template may carry indicia of key functions, particularly when selected ones of the keys 27 become programmed to serve more than one function. A keyboard ribbon cable 259 is communicatively coupled to the main logic board 219.
FIG. 14 is a pictorial composite drawing of major subassemblies as they are ultimately assembled to form the completed data terminal 10, as depicted, for example, in FIGS. 1,2 or 3. Major subassemblies heretofore described include the assembled upper or top housing shell 14 and the assembled base shell 37 including the I/O board assembly 177. A batter cavity cover 261 is of rectangular shape and sized to fit over the battery cavity 176 in the base housing shell 37. The cover 261 has a plurality of peripherally spaced alignment notches 262 which slidingly engage complementary tabs 263 in the base shell 37. The battery cover 261 is interposed in the final assembly of the data terminal 10 between a battery and the main logic board 219. The cover features a number of resilient tabs 264 which would engage and place a contact pressure on an inserted battery 265 (see FIG. 17) to effectively reduce a necessary insertion clearance for insertion of such battery to a minimum and to stably retain an inserted battery within the battery cavity 176. A guard and spacer block 267 is placed along the upper end 19 into position against the upper housing shell 14 during the attachment of the upper housing shell 14 to the base housing shell 37. The spacer block 267 effectively closes off an edge of the main logic board 219 from accidental damage when the memory card door 42 is opened.
The upper housing shell 14 is attached to the base housing shell 37 by a number of laterally spaced screws 268, by a single screw 269 which extends through the base shell 37 through a boss 270 in the spacer block 267 and-into the upper housing shell 14 at the lower end 19 of the housing 12. A second, single screw 271 clamps centrally the two housing shells 14 and 37 at the lower end 20 of the housing 12. A soft and flexible weather seal strip 273 is placed in a peripheral groove 274 which extends along an edge 275 of the base shell 37 that engages and matches with a correspondingly peripheral edge 276 of the upper shell 14.
The peripheral edge 275 features a locating ridge 277 with a number of spaced notches 278. The notches 278 are locating notches for the seal strip 273. Correspondingly spaced protrusions 279 molded onto the otherwise smooth seal strip 273 fit into the notches to securely retain the seal strip 273 within the peripheral groove 274. A representative PCMCIA standard memory card 280 may be inserted into the card connector 189 after assembly of the data terminal 10, but before the memory card door 42 at the upper end of the housing 12 is closed. The memory card door 42 and the battery door 41 are quickly opened or removed and re-attached with the respective quarter turn quick release lock assemblies 43.
FIG. 15 shows the memory card door 42 in greater detail. The door 42 is in major structural details identical to the battery door 41, except for its relatively larger size and a switch activator tab 283 and a memory card retention tab 284 which extend from the memory card door 42 inward into the space of the I/O board assembly 177. Both the battery door 41 and the memory card door 42 have a resilient, impact resistant co-molded rubber exterior and integrated door seal 285. Also both the battery door 41 and the memory card door 42 use the same quick release lock assemblies 43. The lock assembly uses an outer quarter turn knob 286. The knob 286 has a stem 287 which protrudes through a bearing aperture 288 in the respective door into the interior of the housing 12.
An O-ring seal 289 peripherally seals off the aperture 288 after the assembly of the knob 286 to the respective door. A spring washer 291 is placed interiorly over the stem 287 and molded fiats 292 on the end of the stem 287 engage corresponding fiats 293 of a latch lever 294. A screw 295 attaches the latch lever 294 through a fiat washer 296 to the stem 287.
FIG. 16 shows details of the memory card door 42 from an exterior direction, showing outer twist members 297 in the knob 286. The twist members 297 are preferably recessed within the confines of the knob 286. The knob 286 is recessed within a knob cavity 298 to protect the data terminal 10 from damage during a fall should the data terminal 10 be impacted suddenly against one or the other of the doors 41 or 42.
FIG. 17 is a composite drawing of the upper end 19 of the housing 12 of the data terminal 10 in combination with a battery 265 about to be inserted into the battery cavity 176. The view of the upper end 19 of the housing is shown with both the battery door 41 and the memory card door 42 removed from their respective cavity openings. The opened upper end 19 of the housing 12 shows the spacer block 267 in position adjacent the upper housing shell 14.
Further, an end portion of the I/O board assembly 177 is shown, showing the memory card release buttons 193 and 194 in greater detail. Markings on the release buttons 193 and 194 show that the release button 193 releases a memory card from an upper guide slot while the release button 194 releases a lower memory card. A square aperture 301 in an end wall 302 of the base housing shell 37 allows access for the tab 283 to contact and activate a switch which is physically located on the I/O board assembly to signal that the memory card door 42 has been opened and removed. This signal allows the data terminal to save logical states and assume a sleep mode without loosing data and with the ability to resume operation upon closing of the memory card door 42. Optical, magnetic, inductive or other sensing means are known to detect a movement of a mechanical element with respect to another. The use of the described sensing provision for sensing the removal of the door to request a shutdown mode of the data terminal 10 may consequently be modified accordingly.
FIG. 18 is a pictorial view of the handstrap 70 removed from its attachment to the base shell. The handstrap 70 shows the transverse upper attachment end 71 with the two transverse attachment points 72. The strap loop 73 of the attachment end 71 retains the described strap ring 74. The strap 76 is inserted and adjusted in length by pulling more or less of the length of the strap 76 through the strap ring 74. The strap 76 terminates in the bifurcated or forked strap loop 77 which may be placed as shown over the holder bracket 78 with the desirable results as described herein. The holder bracket 78 quickly may be fastened or removed from the data terminal by the described screws or equivalent fasteners. When the strap 76 is looped through the ring 74 it may be attached to itself via convenient hook and loop fasteners in the strap regions 83 and 84. The length of the fastening area 84 is chosen for an effective length adjustment range of the handstrap 70. The hand pad 85 provides cushioning for an operator's hand when inserted between the handstrap 70 and the data terminal.
FIG. 19 shows the handstrap 70 which identical in function to the handstrap 70 described with respect to FIG. 18, but which includes a modified transverse upper end attachment 305 in lieu of the transverse end attachment 71. The attachment points 72 remain nominally spaced as shown in FIG. 18. Also the strap loop 73 holds the strap ring 74. The transverse attachment 305 is, however, bifurcated to straddle an accessory pod (not shown), when an accessory pod, such as the accessory pod 30 in FIG. 3 is used in lieu of the multi purpose grip plate 52 depicted in FIG. 2. If desired, the handstrap 70 as depicted in FIG. 19 may be used in conjunction with either the accessory pod 30 or the multi-function grip plate 52.
VI. Description of FIGS. 20-26
FIG. 20 is a diagram of electronic functions which operate and control the operation of the data terminal 10 in accordance herewith. The functions depicted are essentially found on the logic board 219. A preferred microprocessor device is an AMD 386 microprocessor 310 (MP 386). An address bus 311, a data bus 312 and a control bus 313 couple the microprocessor 310 to a computer device 314 referred to as a "SCAMP" (SCAMP 82C315). The data bus 311 further couples the microprocessor 310 to a DRAM memory device 315 (DRAM). The memory device 242 is removably mounted to the logic board or main circuit board 219 itself through the typical sub-circuit connector socket 243, not separately shown in FIG. 20. The connector socket 243 is a typical device socket which may be commercially obtained to couple a subcircuit such as a memory extension board 242 ("EXT MEMII") to the main circuit board 219.
The SCAMP device 314 is coupled by shared data and address buses 321 and 322, respectively, to the I/O board assembly 177, also referred to as an I/O connector board 177. Connection to the I/O connector board is made through the I/O connector 218 and is schematically shown as a connecting function 218. The SCAMP device 314 is further coupled through a control bus 323 to a communications interface device 325. Row and column address buses 326 and 327 of main application memory devices 315 and 242 are addressed through the SCAMP device 314. The I/O connector or connection 218 interfaces with the application microprocessor 310 via the SCAMP device 314 and the communications interface device 325. Consequently, the connection 218 is further coupled to the SCAMP device 314 by a local address bus 328 and to the communications interface device 325 by an interrupt request bus 329. Flash memory 330 contains initial start up control instruction for the applications microprocessor 310. The flash memory is coupled through the SCAMP device 314 via the shared data and address buses 321 and 322, respectively, and may include a buffer 331 (BF), coupled to the address bus 322. Input and output functions of the I/O connection 218 are best explained in brief reference to FIG. 21.
FIG. 21 depicts functional elements which are, according to the described embodiment, mounted on the special input-output function interface board 177 ("1/0 BDII"), further referred to as I/O board 177. An advantage of the use of the I/O board 177 as an addendum to, but as a separate structural element from, the main circuit board 219, for example, is an increased ease of assembly and a promotion of modular concepts. A use of modular concepts permits the data terminal 10 to be adapted to special uses. In reference to FIGS. 20 and 21 and the preferred functional layout of a combination of the main circuit board 219 and the I/O board 177 shows that substantially all internal operational functions of the data terminal 10, those which are expected to remain the same for most, if not all, applications, are supported by the main circuit board 219. On the other hand, input-output functions may vary among different special use applications of the data terminal 176. The less permanently defined input-output functions are therefore found on the I/O board 177. The data terminal 10 may therefore undergo a basic functional modification by the removal of the I/O board 177 for a different I/O board with different input-output functions. Components on the main circuit board 219 need therefore not be changed. However, with changed input-output functions and parameters, a control program which would be resident in the flash memory 330 may need to be updated to account for changes in operating default settings of now different input-output functions as provided by a different I/O board.
Physically and communicatively, the I/O board 177 is coupled through the I/O connection 218 to the main circuit board 219. The connection 218 may be established between mating I/O connectors 336 and 337 mounted, respectively, to the main circuit board 219 and the I/O board 177. The respective I/O connectors 336 and 337 couple and extend the data and control buses 321 and 322, the local address bus 328 and the interrupt request bus 329 to the I/O board 219. The data and control buses 321,322, the local address bus 328 and the interrupt request bus 329 are depicted in FIG. 21 as an I/0 signal and control bus 340.
A basic version of the I/O board 177 is preferred to include input-output functions as shown in FIG. 21. An Ethernet controller 345 is a commercially available Ethernet controller device. The Ethernet controller is communicatively coupled through the I/O signal and control bus 340 to the data terminal 10. Communication between external devices and the data terminal 10 is obtained through a 28-pin data connector 178 and a bank of coupling elements, such as surface contact assembly 105 of the data terminal 10. Signal pairs 348 and 349 from the Ethernet controller 345 are preferably coupled through an isolation transformer device 350 to external communications couplers, such as to the data connector 178 or to the surface contact assembly 105. It has been determined that parallel connections to both the typical 28-pin type communications connector 178 and surface contacts, such as the surface contact assembly 105 (see, for example, FIG. 2) increases the usefulness of the data terminal 10. Consequently, communications leads 351 and, 352 on an external side of the isolation transformer 350 are coupled to respective terminal contacts of both the 28-pin connector and of the bank of surface contacts 235.
A second desirable communications controller on the I/O board 177 is a Dual UART device 355. The Dual UART (Universal Asynchronous Receive and Transmit) device 355 is coupled internally of the data terminal 10 to the I/O signal and control bus 340 and for external communications to respective RS 232 and RS 485 control circuit devices 356 and 357, respectively. In furtherance of advantages obtained through a dual coupling function via both the connector 178 and surface contacts 235, standard connections of the RS 232 and RS 485 devices are also contemplated to be coupled to designated control and data terminations on the 28-pin connector 178 and respective ones of the surface contacts 235. The portable data terminal 10 may typically not be regarded as the type of device the usefulness of which may be enhanced by linking provisions to communication networks such as Ethernet. However, it has been discovered that a full function of the data terminal 10 is implemented only when an efficient operation of collecting data at the working level of a complex data system is supplemented by equally efficient communications with the data system. In furtherance of this, Ethernet capability is found to provide a communications link of significance. Ethernet may be used, to give but one example, for data exchange with a data system external to the data terminal 10, during docking periods, for example, when batteries are being recharged. External power may temporarily be applied to the data terminal 10 while the data terminal is located in the docking device 110 (see FIG. 4). Such external power may be used to conserve power consumption from the power pack 265 and to recharge the power pack as needed.
A battery charging control circuit 359 is desirably located on the I/O board 177 in that battery charging connections are made through selected terminations of the surface contacts 105. Other external connections, such as any convenient power plug, may of course be provided in addition to designated ones of the surface contacts 105. Smart battery charging control circuits are known and are desirably used within the data terminal 10 itself to provide protection to the data terminal 10 from damage due to improper charging procedures or failure of controls that may otherwise be available in standard battery recharging apparatus (not shown). The control circuit 359 has the function of limiting the magnitude of a charging current that may be admitted to batteries of a power pack 265, for example.
The I/O board 177 is also found to desirably contain a communications control interface device 360 to one or more PCMCIA card slots, preferably the two card connectors 191 and 192, as described above with respect to FIG. 11. Though PCMCIA cards may serve to provide added storage capacity to apparatus, such as a data terminal, known diverse uses for PCMCIA cards most properly allow these cards to be considered data input and output devices, rather than primarily data storage devices. In reference to FIG. 20, a switch 332 may be depressed to recognize a special use card in the respective card slot 191, for example, such that the flash memory 330 on the main circuit board 219 may be updated whenever the presence of a special memory card is detected by the switch 332.
The I/O board 177 further features a pod connector 365, through which connection is made to the respective accessory panel or pod 30 and to any respective data collection or communications device located therewith. The pod connector 365 is communicatively coupled to the I/O signal and control bus 340, just as the Dual UART device 355 and the Ethernet controller 345. The accessory pod 30 may, for example, contain the described bar code scanner. The accessory pod or panel 30 may instead house data communications apparatus, such as an RF transceiver, or a modem. The accessory may be controlled internally by a microprocessor circuit of its own for processing data in accordance with the function of the respective accessory device, the processed data then being transferred to the data terminal 10 via the I/O signal and control bus 340. However, data flow between the data terminal 10 and the accessory pod is preferably controlled by the data terminal 10 by control signals from the main circuit board 219 applied via the I/O signal and control bus 340.
Referring back to FIG. 20, the depicted circuit functions show certain changes and improvements over the circuit functions described in the prior application, Ser. No. 08/048,873, filed Apr. 16, 1993, while retaining the inventive features disclosed therein. Simplifications include a deletion of an optional ROM device, in that the flash memory 330 includes the BIOS for operating the main logic board 219. Also, a memory refresh operation is advantageously executed by the SCAMP device 314 and is not separately shown. An advantageous change provides for a VGA controller device 366 to be addressed directly by the applications microprocessor 310, rather than through the SCAMP device 314, as shown by the routing of the address and data buses 311 and 312, respectively. Video DRAM 367 is coupled directly and interacts directly with the VGA controller 366.
The communications interface device 325 is linked directly with address, data and control buses to both the applications microprocessor 310 and a maintenance microprocessor 368. Static RAM 369 is coupled through respective address and data buses 371 and 372 to the maintenance microprocessor 368. The maintenance microprocessor controls generally maintenance functions such as an LCD contrast control function 375 ("11LCD CON -EL CONTROL") which further represents an EL panel backlighting control for the LCD screen 15. A further control function for the maintenance microprocessor 368 is to monitor the remaining charge or state of charge of the battery or power pack 265. The maintenance microprocessor 368, in functioning as a relatively slow operating control microprocessor, obtains its reset and start up code through the respective maintenance data bus 372 as addressed by the respective maintenance address bus 371 from the static RAM device 369. The maintenance microprocessor device 368 consequently retains its operating code independently of battery voltage levels. In case of memory failure, the maintenance memory 369 may be renewed or rewritten by the applications microprocessor 310 pursuant to programs stored in the flash memory 330, or as further updated via the PCMCIA special functions available through the connector 191 and a special updating card. The maintenance microprocessor 368 further shows an interrupt request bus 385 which is used in the power maintenance function to communicate possible alarm or interrupt conditions between the microprocessor 288 and the communications interface circuit 325. An audio circuit device 386 ("AUDIO") is shown coupled directly to the maintenance microprocessor 368 and the communications interface device 325.
A control bus 407 couples the communications interface device 325 to the VGA controller 296. The switch 332 is manually activated instead of directly by a special memory card, though such an interaction is considered to be an option. In a preferred embodiment the switch may now be operated manually in conjunction with an ON/OFF switch of the data terminal 10 when a special memory card is present and the memory address function is to be altered through the memory card. Though an active pen operated digitizing array may be used, the described touch sensitive pad 229 is preferred as an overlay over the LCD screen 15. An analog to digital signal converter 408 ("ND CONV") is coupled to the touch sensitive screen or pad 229. A touch screen control line 409 leads to the converter 408, and digital signals are obtained via the data bus 410, as obtained from an analog voltage output via line 411 from the touchpad 229
FIG. 22 is a flow chart of an interaction between both a control program as it may reside in memory of the data terminal 10, and certain circuit states of the circuit functions of the circuit board 219, for example. The operation of the data terminal 10 is comprised of separate functions of executing application programs or "performing application tasks," such as collecting, processing or communicating data messages, and a continuous power management procedure. Pursuant to the unique power management procedure which is enabled by the described circuit function, power to the data terminal 10 may be shut down any time the data terminal is not in use, or during any of a number of alarm or defect conditions. Such defect condition may occur when the operating voltage falls below a desired minimum voltage, or when an operator seeks access to the data terminal 10 in a manner which may cause an inadvertent power failure.
Referring specifically to FIG. 22, hardware activity may activate the data terminal 10, for example, by an operator "turning on" the data terminal 10. When a "ICTS" (clear to send) signal goes from low to high, power is applied and the microprocessors 310 and 368 may be reset. At that time the software or the control functions of the data terminal 10 take over. The voltage is checked and would be compared to a preset minimum (or even a maximum) voltage. If the voltage check is "OK," a memory check is performed. If the memory check is passed, all states of the data terminal 10 prior to shut down are restored ("RESTORE STATE"). Thus, whatever operation may have been performed prior to shutdown, the data terminal 10 becomes enabled to resume that operation. Thus, unless other operations are initiated, the ("RESUME") step is executed. If a memory check was failed, a full reset will be performed.
Further in reference to FIG. 22, a timed activity monitoring function may be executed by the maintenance processor 368 (see FIG. 20). For example, if there is no activity within ten seconds, the states of the data terminal 176 are again saved, as well as memory and data states, and the data terminal is powered down, at which time all software functions necessarily stop because of lack of power. It now again takes mechanical or hardware action, as explained, to again power up the data terminal 10. However, because all states are saved, operation of the data terminal 176 is resumed at the point of operation at which power down operation was initiated.
If there is system activity, or if there has been system activity within a preset monitoring period, such as the ten second period, the data terminal 10 will continue to perform its tasks. Voltage levels are polled in preferred intervals. A preferred interval is once every millisecond or 1000 times per second. This polling activity is an activity performed by the maintenance microprocessor 368. As soon as a low voltage condition is detected, the shut down sequence is initiated. The active states are saved to shadow RAM, and the data terminal is powered down by removing power. Further activity stops, but the most recent active states of all devices including the I/0 states, are preserved. Thus, when an operator pushes a designated keyboard function switch, for example, the operation of the data terminal 10 may be resumed.
FIG. 23 shows preferred functions of the communications interface circuit 325. The respective address, data and control buses from the microprocessors 310 and 368 lead into a processor interface and contention resolution circuit 415. From the interface 415, an address bus 416 and a data bus 417 provide for selective addressing and operation of an A/D converter function 418, a sleep mode function 419, the control 420 of interaction between the applications and maintenance microprocessors, the maintenance microprocessor interrupt control 421 and a general system control function 422 which addresses and operates the various other functions as herein before described, and through which status data may be received via status bus 423. The communications interface circuit is further improved with a maintenance processor master mode function 425. The master mode function 425 may be triggered by a signal to the from the communications interface circuit 325 to the applications microprocessor 310 to tri-state or neutralize output signals from the microprocessor 310. The tri-stating signal is applied via control line 426 effectively rendering the applications microprocessor non-functional. The procedure may be used in conjunction with a special memory card on start up, by depressing the switch 332 shown in FIG. 20 in conjunction with powering up the data terminal 10. The procedure may be used when the BIOS program residing in the flash memory device 330 (FIG. 20) has become defective and is to be restored, or when a new BIOS is to be loaded into the flash memory device 330. Accordingly, during such controlled start up, the maintenance microprocessor 368 takes over the setup function of the data terminal, acting in place of the applications microprocessor 310 to cause the microprocessor 310 upon a further reset command to address the special memory card from the card slot 191, for example, instead of fetching instructions from the flash memory 330.
FIG. 24 shows details of the master mode function 425. Control, data and address codes from the maintenance microprocessor 368 through bus 427 are converted via respective control address and data communications functions and through a state machine 428, though at the rate of the microprocessor 368 through output buses 429 as if stemming from the applications processor 310.
FIG. 25 shows a sequence diagram whereby in step 431 the communications interface 325 checks the special key and enables the master mode just described. In step 432 the microprocessor 310 is disabled by the tri-state mode via a signal over control line 426. At 433 the microprocessor 368 takes over as described to set flags and registers to direct communications of the microprocessor 310 to the special PCMCIA card at the slot 191, for example. In step 434, the microprocessor 434 is reset, and while reset is taking place, the maintenance or control microprocessor 368 disables through step 435 the signal at 426, returning the applications microprocessor to its normal operation. However, because of the specially set flags and registers, the SCAMP device 314 directs the request for data from the microprocessor 310 instead of to the flash memory 330 to a PCMCIA controller 436 located on the I/O board 177.
FIG. 26 shows a data flow during such altered address states. The microprocessor 310 bypasses the flash memory 330 and instead sends and receives data and address codes through the SCAMP device 314 and respective buses 321 and 322 and through the controller 436 from a special memory card 437.
VII. Description of FIGS. 27-30
FIG. 27 is a block diagram of a second embodiment of the components necessary to operate and control the operation of the data terminal 10 in accordance herewith. This second embodiment shares many common features with the first embodiment previously described. The functionality of the second embodiment is an expansion of the logical arrangement and operation of the applications microprocessor 1014 and the maintenance microprocessor in order to further reduce power consumption. A preferred main terminal microprocessor device in the second embodiment is an AM386SXLV processor 1014 (CPU 386SXLV). The microprocessor 1014 connects through the Local Bus 2000 to a computer interface device 1022 referred to as an ASIC interface. The ASIC interface 1022 is further connected to the maintenance microprocessor 1018. The Maintenance microprocessor 1018 is preferably an H8/330 very low power microcontroller (MUP).
The applications microprocessor 1014 and the maintenance microprocessor 1018 connect to the ASIC interface 1022 to form a shared bus dual processor architecture in which communications with the device buses can be accomplished by either microprocessor. The maintenance microprocessor 1018 is interfaced to the applications microprocessor 1014 through the ASIC 1022 via a back-to-back port structure that allows bytes of data to be written by one processor and read by the other, effectively implementing a single byte dual port RAM. The ASIC interface 1022 coordinates data movement by providing a method for the processors to indicate to each other when a byte of data has been made available by one processor and when it has been read by the other. The addresses, data and control lines of the maintenance microprocessor 1018 are interfaced to the ASIC 1022 to control the applications microprocessor 1014 interface logic block as well as to allow the maintenance microprocessor 1018 to have access to the applications microprocessor 1014 input/output channels for control purposes. The main function of the maintenance microprocessor 1018 is control of the data terminal 10 through port control of logic signals.
In this arrangement the maintenance microprocessor 1018 monitors activity and performs control and peripheral management tasks while the main processor is essentially shut down. When an application requires, the applications microprocessor 1014 will become active to perform the processing task as required by the application. Upon completion of the task the applications microprocessor 1014 is shut down and operations are resumed by the maintenance microprocessor 1018. This arrangement, a key component of system power management, takes advantage of the lower power consumption of the maintenance microprocessor 1018 while maintaining the computational power of the applications microprocessor 1014. System control functions are implemented transparently to the user and PC compatibility is maintained. As a result of this arrangement the applications microprocessor 1014 may perform operations at higher clock speeds without extensively taxing long term battery power since the applications microprocessor 1014 operates only for the duration of the given application and then is shut down immediately upon completion of the application.
The maintenance microprocessor 1018 is supported by the static RAM memory 1016. To accommodate software errors, updated maintenance microprocessor code can be loaded into the flash memory 1036 and then downloaded into the static RAM 1016 to correct these errors. All other software in the data terminal 10 is completely downloadable.
A PCMCIA controller 1030, preferably a Cirrus Logic PD6720 controller, controls the interface to PCMCIA peripheral cards. The PCMCIA controller directs communications with two PCMCIA device slots, 1032 and 1034, one type II and one type III, to allow for flexibility of memory and input/output card combinations.
The ASIC device 1022 directly connects with the PCMCIA Controller 1030 and additionally connects through the Local Bus 2000 to a VLSI Controller 1024 (VL82C315A VLSI Controller, also known as a "SCAMP II"). The VLSI controller 1024 connects with both the Local Bus 2000 and with the ISA Bus 2006 as well. In this arrangement the VLSI controller 1024, a mixed supply device, is the main interface between the devices operating at 3.3 volts 2002 in the Local Bus 2000 and the devices operating at 5.0 volts 2004 in the ISA Bus 2006. Communications to PCMCIA peripheral devices through the PCMCIA Controller 1030 and to the VLSI Controller 1026 are accomplished by either the maintenance microprocessor 1018 or the applications microprocessor 1014 through the ASIC interface 1022. This allows for the advantage of operation of peripheral communications with both low power 3.3 volt peripheral devices and standard type 5.0 volt peripheral devices. Maximum power efficiency is maintained when the majority of bus accesses are confined to the Local Bus 2000.
The VLSI controller 1024 connects through the ISA Bus 2006 to the flash memory 1036. The flash memory 1036 is used as the primary semi-permanent storage mechanism, providing storage space for the applications microprocessor 1014 and the maintenance microprocessor 1018. Writing of the flash memory 1036 is performed by the applications microprocessor 1014. In the event that no valid information has been previously stored in the flash memory 1036 to allow operations of the applications microprocessor 1014 to proceed, the maintenance microprocessor 1018 configures the PCMCIA controller 1030 to execute from a PCMCIA memory card containing a flash memory loader program.
The VLSI controller 1024 is additionally coupled through the ISA Bus 2006 to a Dual UART device 1040 ("DUAR/T PC16552"), preferably a National Semiconductor PC16552. This device allows for data to be captured and buffered while the system is still responding to an initial data ready interrupt, allowing for recovery time from a standby mode. The Dual UAR/T device 1040 allows for connection to standard RS-485 devices 1038 and standard RS-232 devices 1042.
As discussed in the first embodiment of the electronic functions, it is advantageous to have Ethernet capability, which is accomplished by communications through the ISA Bus 2006 to the Ethernet Controller 1042 ("Ethernet Controller Am79C960"). The Ethernet controller 1042 provides high performance communication capability for rapid transfer of data from the data terminal 10 to the LAN 1044 (Local Area Network).
The VLSI controller 1024 further connects to the dynamic RAM memory 1026 (DRAM) which is used for the bulk of the memory capacity. Data integrity is guaranteed by refreshment of the dynamic RAM memory at regular intervals by the VLSI controller 1024 under all conditions. The dynamic RAM memory 1028 may be expanded through Memory Expansion slots 1028.
Timing control is maintained by a clock generator 1008 ("AV9128 Clock Generator"). The clock generator 1008 output is coupled with the input of the VLSI controller 1024 which provides multiple clocks and clock controls in order to achieve PC compatibility and power control. Power consumption is minimized by reducing or stopping clock speeds whenever possible.
A key building block for terminal functionality and PC compatibility is the display controller 1012 ("VGA Controller"). This controller is preferably an SMOS 8107F VGA controller which is connected to the video RAM 1010 for video memory. With the display controller 1012 a full 640.times.480 pixel display exists logically, but only the pixels present in the display panel 1006 ("LCD Module") are visible, which is a 320.times.480 pixel display. The video RAM 1010 is controlled by the display controller 1012 in such a manner as to appear logically as a standard video interface to the applications microprocessor 1014. Display commands and data are transferred to the video system through the Local Bus 2000. The video display system is driven by both the applications microprocessor 1014 and the ASIC 1022. The ASIC 1022 can place the display subsystem into a low power no-visible standby mode, allowing display data to be retained in the video RAM 1010 using its refresh mode. Because of timing and logic incompatibility between the display controller 1006 and the drivers in the display panel 15, the ASIC 1022 modifies the interface signals in order to achieve proper display operation.
Various alternative embodiments of the display panel 15 can be contemplated utilizing the aforementioned display system. These variations are adaptations of the physical dimensions of the data terminal 10 to the needs of a particular user. For example FIG. 29 illustrates an alternative embodiment of the data terminal 10 wherein a larger video display panel 4002 is required by the user such as a full VGA 640.times.480 pixel display. The physical housing of the data terminal 10 would be altered to data terminal 10a in order to accommodate the larger display screen size. Another alternative embodiment illustrated in FIG. 30 would contemplate a smaller video display panel 4004 which is logically a full 640.times.480 pixel display but displayed physically on a reduced sized pixel display, such as a 320.times.240 pixel display, allowing for a corresponding reduction in the physical size of the data terminal 10 to that shown as 10b.
The keyboard control circuit lock 1020 includes logic to allow keyboard scanning by either the maintenance microprocessor 1018 or the applications microprocessor 1014 as well as logic that allows the maintenance microprocessor 1018 to emulate a standard keyboard controller. The keyboard circuit 1020 connects through the ASIC interface 1022.
FIG. 28 is a block diagram depiction of the power supply system 3002 which has components on both the main logic board and the input/output board. All of the voltage regulators in the power supply receive their power from the terminal battery voltage 3006 which is either a NiCad type or a metal hydride type. The charging algorithm is identical for both types of cells. New cell types such as alkaline cells may be implemented in the future by downloading the required battery charging software algorithm into the static RAM 1016 of the maintenance microprocessor 1018 or stored in the flash memory 1036.
One of the unique features of the data terminal 10 in this embodiment is that the power supply 3002 is never turned off. Instead, power is conserved by placing high power consuming devices, such as the applications microprocessor 1014, into the standby state and thereby reducing the power consumed. Additionally, certain supply outputs may be placed into standby mode for power conservation, but the main supplies VCCLOC 3108 and VCCISA 3016 are always operating and supplying power. If the main battery is removed the terminal may still be powered by the backup battery 3008 or the battery charge circuit 3004 if charge voltage is available.
The VCCLOC supply 3018 provides power to the 3.3 volt devices. Most of the power of the data terminal 10 is supplied by the VCCLOC supply 3018, therefore it is essential that it be the most efficient power supply.
In view of the above detailed description of a preferred embodiment and modifications thereof, various other modifications will now become apparent to those skilled in the art. The claims below encompass the disclosed embodiments and all reasonable modifications and variations without departing from the spirit and scope of the invention.
1. A portable data collection terminal for electronic collection and processing of data wherein data is represented as electrical states for storage in volatile and non-volatile memory, said portable data collection terminal comprising:
- (a) a housing including a display screen and a keyboard disposed on a frontal side of the housing;
- (c) a data input screen including graphic data input means disposed coincident with a screen area of said display screen;
- (d) a power management circuit being disposed within said housing for controlling power consumption of the portable data collection terminal, including means for saving electrical states whereby input and output device states are saved to said non-volatile memory;
- (e) said power management circuit including means for efficient distribution of control of operations between at least two microprocessor devices, said at least two microprocessor devices comprising a lower power consuming management microprocessor and a higher power applications microprocessor;
- (f) a communications interface circuit for shared bus communications and access between said at least two microprocessor devices, said communications interface circuit implementing a bus structure that allows data written by one of said at least two microprocessor devices to be read by the other of said at least two microprocessor devices;
- (g) operation control means for controlling said data terminal by said lower power consuming management microprocessor while said higher power applications microprocessor remains inactive;
- (h) means for activating said applications microprocessor when operations require; and
- (i) means for deactivating said applications microprocessor upon task completion wherein control is resumed by said management microprocessor.
2. The portable data collection terminal according to claim 1, wherein said means for saving electrical input and output states to non-volatile memory includes means for trapping input-output instructions and to shadow write trapped input-output instructions to non-volatile memory during normal operations of the portable data collection apparatus.
3. The portable data collection terminal according to claim 1, wherein said means for efficient distribution of control of operations between at least two microprocessors includes means for the microprocessors to indicate when data is made available by one microprocessor and read by the other microprocessor, including means for shared management, implementation and control of system functions and including means for shared access to the system buses.
4. The portable data collection terminal according to claim 1, comprising further an accessory pod including a handgrip extension pod for holding a selected accessory device of the data collection terminal, said handgrip accessory pod having a width less than the width of the data collection terminal and being disposed on an underside of the data collection terminal and beneath the frontal side of the data collection terminal, whereby said display screen is protected from accidental contact by a user when holding onto said handgrip extension pod.
5. The portable data collection terminal according to claim 4, wherein said accessory device is a scanner.
6. The portable data collection terminal according to claim 1, further including a pen gripping holder molded into an end of the data collection terminal.
7. The portable data collection terminal according to claim 1, further including a memory card door having a seal and means for signaling movement of said memory card door from a locked position.
8. The portable data collection terminal according to claim 1, further including co-molded shock protection means.
9. The portable data collection terminal according to claim 1, wherein said keyboard operates in parallel with said graphic data input means whereby said keyboard and said graphic data input means operate independently of each other with separate interrupt signals such that operation may instantaneously switch from one to the other.
10. The portable data collection terminal according to claim 9, wherein said graphic data input means is a touch sensitive screen.
11. The portable data collection terminal according to claim 1, further comprising an accessory extension pod for holding a selected accessory device of the data collection terminal, said handgrip accessory pod having a width less than the width of the data collection terminal and being disposed on an underside of the data collection terminal and beneath the frontal side of the data collection terminal, whereby said display screen is protected from accidental contact by a user when holding onto said handgrip extension pod.
12. The portable data collection terminal of claim 10 wherein said accessory extension pod includes a radio frequency transceiver.
13. A portable data collection system for electronic collection and processing of data wherein data is represented as electrical states for storage in volatile and non-volatile memory, said portable data collection comprising:
- (a) a data terminal having
- (1) a housing including a display screen and a keyboard disposed on a frontal side of the housing;
- (2) a data input screen including graphic data input means disposed coincident with a screen area of said display screen;
- (3) a power management circuit being disposed within said housing for controlling power consumption of the portable data collection terminal, including means for saving electrical states whereby input and output device states are saved to said non-volatile memory;
- (4) said power management circuit including means for efficient distribution of control of operations between at least two microprocessor devices, said at least two microprocessor devices comprising a lower power consuming management microprocessor and a higher power applications microprocessor;
- (5) a communications interface circuit for shared bus communications and access between said at least two microprocessor devices, said communications interface circuit implementing a bus structure that allows data written by a one of said at least two microprocessor devices to be read by the other of said at least two microprocessor devices;
- (6) operation control means for controlling said data terminal by said lower power consuming management microprocessor while said higher power applications microprocessor remains inactive;
- (7) means for activating said applications microprocessor when operations require; and
- (8) means for deactivating said applications microprocessor upon task completion wherein control is resumed by said management microprocessor; and
- (b) a docking device with one or more docking cavities for receiving and removably retaining said data terminal during storage, data transfer or battery charging operations.
14. The data collection system of claim 13 wherein said docking cavities include offset interposed electrical contact springs for transfer of data between said data terminal and said docking device.
15. The data collection system of claim 14 wherein said docking cavities include means for securely retaining said data terminal remains in continuous contact with said contact springs while said data terminal is docked within said cavity.
16. The data collection system of claim 13 wherein said docking cavities include offset interposed electrical contact springs for battery charging operations.
17. The data collection system of claim 16 wherein said docking cavities include means for securely retaining said data terminal remains in continuous contact with said contact springs while said data terminal is docked within said cavity.
18. The data collection system of claim 13 wherein said docking device includes means for remote electronic data transfer.
19. The data collection system of claim 18 wherein said means for remote electronic data transfer includes means for infrared data transmission.
20. The data collection system of claim 18 wherein said means for remote electronic data transfer includes means for radio frequency transmission.
21. The data collection system of claim 18 wherein said means for remote electronic data transfer includes means for communications on a local area network.
22. The data collection system of claim 12 wherein said docking device includes means for recharging the battery of said data terminal.
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Filed: Jul 7, 1995
Date of Patent: Oct 21, 1997
Assignee: Norand Corporation (Cedar Rapids, IA)
Inventors: Dennis Silva (San Jose, CA), Paul Beard (Milpitas, CA), Steven Darren Friend (Felton, CA), Daniel E. Alt (Marion, IA), Rickey G. Austin (Lisbon, IA), Darrell L. Boatwright (Cedar Rapids, IA), Arvin D. Danielson (Solon, IA)
Primary Examiner: David H. Malzahn
Law Firm: Suiter & Associates PC
Application Number: 8/499,593
International Classification: G06F 132;