Patent Abstract:
Apparatus for reprogramming a programmed controller of a power driven wheelchair comprises: a reprogrammable, non-volatile memory programmed with a plurality of programs executable by the controller to operate the wheelchair, the non-volatile memory disposed at the wheelchair and coupled to the wheelchair controller; a general-purpose computer programmed to reprogram the non-volatile memory while disposed at the wheelchair, the programmed computer for storing main programs for use in reprogramming the non-volatile memory, the programmed computer being coupleable to the wheelchair controller for accommodating an exchange of data therebetween; and wherein the wheelchair controller being operative to communicate with the programmed computer to reprogram the non-volatile memory with the main programs while the non-volatile memory is disposed at the wheelchair. Methods for reprogramming the non-volatile memory are also disclosed.

Full Description:
BACKGROUND OF THE INVENTION 
     The present invention is directed to the field of power driven wheelchairs, in general, and more particularly, to a method and apparatus for reprogramming a programmed controller of a power driven wheelchair. 
     Power driven wheelchairs which may be of the type manufactured by Invacare Corporation of Elyria, Ohio, for example, generally include right and left side drive wheels driven by a motor controller via respectively corresponding right and left side drive motors, all of which being disposed on the wheelchair. An exemplary illustration of such a motor drive arrangement is shown in the schematic of  FIG. 1 . Referring to  FIG. 1 , a motor drive controller  10  which may be an Invacare MK IV™ controller, for example, controls drive motors  12  and  14  which are mechanically linked respectively to the right side and left side drive wheels of the wheelchair. The controller  10  includes a microcontroller  15  which may be programmed with a plurality of drive programs, each suited for a particular operating environment of the wheelchair. 
     A user interface  16  which may include a joystick  18  and selection switches (not shown) operable by a user is also disposed on the wheelchair in a convenient location to the user. The user interface  16  is generally interfaced to the microcontroller  15  over a two wire serial coupling  20  to permit the user to select a drive program appropriate for operating the wheelchair in its environment and to adjust the direction and speed of the wheelchair within the selected drive program. In the present example, a main program of the microcontroller  15  which may contain the plurality of drive programs is stored in a non-volatile memory  19 , like a read only memory (ROM), for example, which may be integrated into the microcontroller  15  or may be a separate component thereof. 
     The motor controller  10  is generally powered by a battery source  22 , which may be 24 volts, for example, also disposed on the wheelchair. The drive motors  12  and  14  may be of the permanent magnet type and may be either a gearless, brushless AC motor or a brush type DC motor. The microcontroller  15  is interfaced and responsive to the user interface  16  to control drive signals  24  and  26  to motors  12  and  14 , respectively, via a power switching arrangement configured in accordance with the motor type being driven. The power switching arrangement may be powered by the 24V battery  22 . Thus, as the user adjusts the speed and direction of the wheelchair via the joystick of interface  16 , appropriate drive signals  24  and  26  are controlled by motor controller  10  via microcontroller  15  to drive the motors  12  and  14  accordingly. 
     Motor controller  10  generally controls motor speed to the user setting utilizing a closed loop controller programmed in the microcontroller  15 . Actual speed of each motor  12  and  14  may be derived from signals  28  and  30  respectively sensed therefrom. For example, for AC motors, a Hall Effect sensor may be disposed at the motor for sensing and generating a signal representative of angular position. The signals  28  and  30  are coupled to the microcontroller  15  which may be programmed to derive motor speed from a change in angular position for use as the actual speed feedback signal for the closed loop speed control of the motor. For DC motors, the voltage Va across the armature and armature current Ia may be sensed from each motor  12  and  14  and provided to the microcontroller  15  via lines  28  and  30 , respectively. Microcontroller  15  may under programmed control derive the actual speed of each motor  12  and  14  from the respective voltage Va and current Ia measurements thereof for use as the speed feedback signal for the respective closed loop speed control of each motor  12  and  14 . 
     In addition, interaction with the motor controller  10  is performed through a remote programmer  34  which may be electrically coupled to a port of the microcontroller  15  via signal lines  36 , for example. Each remote programmer  34  may include a screen  38  for displaying interactive text and graphics and a plurality of pushbuttons  40  for communicating with the microcontroller  15  which is programmed to interact with the programmer  34 . A dealer is generally provided with one or more remote programmers for rendering the wheelchair unique to the user&#39;s safe operating capabilities. 
     From time to time, the non-volatile ROM  19  may have to be reprogrammed and/or updated to more recent program versions which may be accomplished either in the field or at the factory or a service center. In some motor controllers, the programmed ROM  19  may be embodied in an integrated circuit or chip, either as part of the microcontroller  15  or separate therefrom. In these cases, the chip containing the programmed ROM  19  is removably disposed in a socket of a printed circuit (PC) card of the motor controller assembly  10 . If the ROM  19  has to be reprogrammed or updated, the chip is removed from the socket and sent to the factory or authorized service center for processing. This renders the wheelchair out of service for an undesirable period of time. 
     Alternatively, some wheelchair dealerships are equipped with specialized converters and programming devices which permit reprogramming or updating of programs of the ROM  19  on the PC card. Generally, this process is not performed by a lay person, but rather performed by a skilled technician employed by the dealership. In these instances, the cost of the specialized equipment and skilled technician is borne by the dealership. 
     The dealers would prefer servicing the wheelchair themselves without having to send components back to the factory or service centers for reprogramming and/or updating of operational programs. However, the expense of the specialized equipment and employment of a skilled technician for performing this service is quite onerous to the dealer. Accordingly, it is desirable to simplify the process of reprogramming and/or updating the operational programs of the wheelchair at least to the point where it may be performed by a lay person. The present invention satisfies this desire. 
     SUMMARY OF THE INVENTION 
     In accordance with one aspect of the present invention, apparatus for reprogramming a programmed controller of a power driven wheelchair comprises: a reprogrammable, non-volatile memory programmed with a plurality of programs executable by the controller to operate the wheelchair, the non-volatile memory disposed at the wheelchair and coupled to the wheelchair controller; a general-purpose computer programmed to reprogram the non-volatile memory while disposed at the wheelchair, the programmed computer for storing main programs for use in reprogramming the non-volatile memory; means for coupling the programmed computer to the wheelchair controller for accommodating an exchange of data therebetween; and wherein the wheelchair controller being operative to communicate with the programmed computer through the coupling means to reprogram the non-volatile memory with the main programs while the non-volatile memory is disposed at the wheelchair. 
     In accordance with another aspect of the present invention, a method of reprogramming a programmed controller of a power driven wheelchair comprises the steps of: coupling a reprogrammable, non-volatile memory programmed with a plurality of programs to the wheelchair controller; determining if the plurality of programs of the non-volatile memory are to be reprogrammed; coupling a programmed computer to the wheelchair controller based on the result of the determining step, the computer being programmed to reprogram the non-volatile memory through the wheelchair controller; displaying an interactive programming screen image on a display of the programmed computer; and interacting with the programming screen image to control reprogramming the non-volatile memory through the wheelchair controller. 
     In accordance with yet another aspect of the present invention, a method of reprogramming a programmed controller of a power driven wheelchair comprises the steps of: partitioning a reprogrammable, non-volatile memory into at least two sections; programming one section of the non-volatile memory with a boot program executable by the wheelchair controller; programming another section of the non-volatile memory with main programs executable by the wheelchair controller to operate the wheelchair; executing the boot program by the wheelchair controller to determine if the main programs of the non-volatile memory are to be reprogrammed; coupling a programming device to the wheelchair controller based on the result of the determination; and interacting with the programming device to control a reprogramming of the main programs of the non-volatile memory through the wheelchair controller. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram schematic of an exemplary motor drive arrangement of a power driven wheelchair including a programmed microcontroller. 
         FIG. 2  is a block diagram schematic of apparatus for reprogramming the microcontroller suitable for embodying the principles of the present invention. 
         FIG. 3  is an illustration of an exemplary joy stick unit suitable for use in the embodiment of  FIG. 2 . 
         FIG. 4  is a block diagram schematic of a sectioned non-volatile flash memory suitable for use in the embodiment of  FIG. 2 . 
         FIGS. 5A and 5B  (collectively  FIG. 5 ) depict a flow chart of an exemplary boot program suitable for being programmed in a section of the non-volatile flash memory of  FIG. 4 . 
         FIG. 6  is an illustration of an exemplary interactive screen image of a personal computer suitable for use in reprogramming the flash memory of  FIG. 4 . 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 2  is a block diagram schematic of reprogramming apparatus suitable for embodying the principles of the present invention. Referring to  FIG. 2 , a reprogrammable non-volatile memory  50  which may be a programmable system device (PSD) or flash memory, for example, is coupled to the microcontroller  15  via address (A), data (D) and control (C) lines thereof. The flash memory  50  may be integrated within the integrated circuit or chip of the microcontroller  15  or contained on a separate chip which may be of the type manufactured by ST Microelectronics under the model no. PSD913F2, for example. The flash memory  50  is initially programmed at the factory. 
     The flash memory  50  may be reprogrammed in the field while soldered in place on the PC board of the microcontroller  15 . Thus, no special connector or programming device is needed. The flash memory  50  may be reprogrammed using a similar process to reprogramming an electrically erasable programmable read only memory (EEPROM), except that the flash memory may be reprogrammed at a much faster rate. For example, an EEPROM is generally reprogrammed at a rate of about one byte of memory per ten milliseconds. Thus, for tens of thousands of bytes of memory, reprogramming of an EEPROM takes a very long time. However, the flash memory  50  may be reprogrammed at a rate of approximately one byte per thirty microseconds or approximately thirty-two bytes per one millisecond, thereby shortening the reprogramming period by orders of magnitudes as will become more evident from the description herein below. 
     The flash memory  50  may be partitioned into two memory sections as shown in the illustration of  FIG. 4 . One section  52  of memory  50  stores a first or boot program, and the other section  54  stores a second or main program which comprises the drive and application programs for operating the wheelchair. The memory registers of the main program  54  may be sectioned into a plurality of pages with each page containing thousands of registers, each for containing a byte of data. For example, the main program may be sectioned into 7 pages of registers as shown in  FIG. 4  with each page containing sixteen thousand byte registers, each byte register including eight bits. Coded words may be stored in predetermined registers of the main program section for use in determining if the main program is complete and acceptable for execution by the microcontroller  15 . 
     In the present embodiment, a coded word is stored in the last byte register of each page of the main program as a signature byte for analysis. Thus, the byte registers of the non-volatile flash memory  50  may be programmed a page at a time with the signature coded word programmed in the last byte register for each page. Accordingly, if a properly coded word is found in the last byte register of a page in the flash memory, then it is presumed that all of the preceding byte registers were programmed properly. It is understood that signature coded words may be programmed into other byte registers of memory  50  without deviating from the broad principles of the present invention. 
     In an alternate embodiment, a coded word representative of a check sum value of all of the registers of the main program section may be loaded into one or more predetermined byte registers of the main program. Accordingly, the microcontroller  15  may execute the boot program to add up all of the values of the byte register contents of the main program section and compare the total value with the check sum value in the predetermined byte registers. In this alternate embodiment, the check sum value is intended to cover all of the main program registers, but it is understood that the main program section may be broken down into subsections or pages just as well. In which case, a coded word representative of a check sum value for each page may be loaded into a predetermined register or registers of the page, for example. Thus, execution of the boot program would result in adding up the values of the byte register contents of each page and comparing each total value with the corresponding check sum value of each page to determine if the main program is complete. 
     In yet another embodiment, the coded word may be representative of a cyclic redundancy check (CRC) value. In this embodiment, the boot program may include an algorithm for performing a CRC of the registers of the main program which results in a rather unique value which may be compared to the CRC coded word contained in the predetermined registers of the main program section. Similarly, the main program section may be broken down into subsections or pages just as well. In which case, a coded word representative of a CRC value for each page may be loaded into a predetermined register or registers of each page, correspondingly. Thus, execution of the boot program would result in performing the CRC algorithm on the byte register contents of each page and comparing each calculated CRC value with the corresponding CRC value of each page to determine if the main program is complete. 
     In the present embodiment, upon power-up of the microcontroller  15 , program execution starts in the boot program of section  52 , a description of which being provided herein below in connection with the exemplary flow chart of  FIG. 5 . During execution of the boot program, the microcontroller  15  accesses the data of predetermined registers from the main program section of memory  50 , which may be the last byte registers of the pages, for example, and determines if the accessed registers contain the respective proper code words CW 1 , CW 2 , . . . , CW 7 . If any of the accessed registers does not contain the proper code word, which may be all zeros, for example, then, the microcontroller  15  presumes that the main program has been loaded into the flash memory improperly and shuts down, i.e. does not permit execution of the main program. Otherwise, program execution diverts to the main program for proper operation of the wheelchair. Some or all of the main program may be stored in a temporary memory  53  which may be integrated into the microcontroller  15 . 
     In the present embodiment, when the boot program shuts down, it enters into a wait loop waiting for commands to reprogram the non-volatile flash memory  50 . These reprogramming commands may be directed to the microcontroller  15  through the user interface  16  which may be a joy stick unit, for example. An exemplary joy stick unit  16  suitable for use in the embodiment of  FIG. 2  is shown in  FIG. 3 . Referring to  FIG. 3 , the unit  16  includes the joy stick  18  and further comprises a liquid crystal display (LCD)  55 , a drive select on/off switch  56 , a speed control  58 , a charger/programming port  60 , the serial communication cable  20  having a connector  62  at one end, an optional drive select port  64 , and a remote on/off port  66 . When the boot program is in the wait loop, nothing will be displayed on the LCD  55  of the joy stick unit  16  which is an indication that reprogramming of the flash memory  50  is needed. 
     To initiate the reprogramming process of the flash memory  50 , a programming device, like a general purpose personal computer (PC)  70 , for example, may be connected to the microcontroller  15 . Since the microcontroller  15  is already programmed to interface with the user interface  16 , i.e. to receive and respond to commands therefrom as described herein above in connection with the embodiment of  FIG. 1 , it is convenient to couple the PC  70  to the microcontroller  15  through the user interface  16 . For this purpose, a serial communication cable  72  may connect a serial port of the PC  70  to the charger/programming port  60  of the unit  16 . The PC  70  may be a lap top unit, for example, having a key board  74  and a display screen  76 , and programmed to reprogram the flash memory  50  through the microcontroller  15 . The PC  70  may be loaded with the appropriate main program for the flash memory  50  based on the product code and/or version code of the motor controller of the wheel chair. The loading of this main program file into the PC  70  may be accomplished through a number of different ways, including downloading the main program file from a compact disk memory or a memory diskette supplied from the manufacturer, for example. 
     The appropriate main program file may even be downloaded from the manufacturer&#39;s website utilizing a communication connection through a modem  78  which may be coupled externally to the PC  70  over a cable  80  or be integrated into the PC  70 . More specifically, the dealer may connect to the manufacturer&#39;s website via the modem  78  and, interacting through screen  76  and keyboard  74 , enter the product code and/or version code for the most recent version of the main program for the flash memory  50 . Through an interactive process with the PC  70 , either over the web or through a compact disk or diskette memory, the dealer may select, download and communicate the downloaded main program to the microcontroller  15  which stores the received main program into a memory file of temporary memory  53 , for example, for use in reprogramming the main program registers of the flash memory  50 . An exemplary display screen suitable for use in reprogramming the flash memory  50  will be described herein below in connection with the illustration of  FIG. 6 . 
     In addition, there may be times when the dealer desires to update the main program code of the flash memory  50  to a more recent version. For this purpose, during execution of the main program  54 , a polling of the programming port  60  of the user interface unit  16  is performed by the microcontroller  15  to determine whether or not a command is present to update the program stored in the flash memory  50 . For example, the PC  70  may be connected to the user interface  16  via cable  72  and may issue a program update command to the microcontroller  15  through the user interface  16 . When the microcontroller  15  receives a command to either reprogram or update the program code of the flash memory  50 , it directs program execution to an erase and loading program which may be in the boot section of the flash memory  50 . 
     Thus, to reprogram or update the programs of the flash memory  50 , an individual may connect the PC  70  to the programming port  60  of the joy stick unit  16  utilizing the serial communication cable  72  and then enter into a flash memory programming program which is installed on the PC  70 . Upon entering the flash memory programming program, proper programming commands are communicated to the microcontroller  15  which responds by entering into the erase and loading program of the boot programs. An interactive image display will also appear on the display screen  76  to aid the individual in programming the flash memory  50 . An example of an interactive display screen for programming is shown in  FIG. 6 . Note that the individual need only follow the steps of the interactive screen image. Selections through the screen display may be performed by movement of a cursor to the proper position on the screen and depression of a key or activation device, for example. 
     For example, if the program file is being downloaded from a memory device inserted into a d:\controller of the PC  70 , then the individual may select the proper file from a window  100  as exemplified by the highlighted file “MS5 — 9S12”. Upon selection, all of the programs of the file MS5 — 9S12 are displayed for selection in a window  102 . The individual may then select the proper main program from the window  102  as exemplified by the highlighted program “m5gb3v56.s19”. Note that the selected program is also shown in window  103 . In step  2 , the individual may select the proper COM port for communicating with the microcontroller  15 . In the present example, COM port  1  is selected as exemplified by the dot displayed in the circle  104 . 
     In step  3 , the individual may select the “File” window  106 , and in response the PC  70  will display in windows  108  and  110  the product code and version, respectively, of the selected main program “m5gb3v56.s19”. In step  3 , the PC  70  will also display text at position  112  to verify that the main program file has been read in from the memory device and stored into the memory of the PC  70 . Then, in step  4 , the individual may select the “Controller” window  114 , and in response the PC  70  will communicate with the microcontroller  15  via user interface  16  to read in the product code and version of the main program currently existing in the flash memory  50 . This information is then displayed in windows  116  and  118 , respectively. In step  4 , the PC  70  will also display text at position  120  to indicate that it has successfully connected to the microcontroller  15  and is ready for programming the flash memory  50  with the selected program file. Note that if the product and version codes are the same for both the selected and current main programs, then no updating may be needed. Also, if the product code does not match or the file is an earlier version, updating may be prevented. 
     In step  5 , the individual may select “Program Flash” at window  122  to initiate the programming of the flash memory with the selected main program file. During the initial steps of the programming process, the registers of each of the seven pages of the flash memory main program are erased via the erasing and loading program executed by the microcontroller  15  and the status of erasure of the seven pages is determined by the PC  70  and displayed at position  124  on the interactive screen. Then, as the main program of the flash memory  50  is programmed, the status of the programming is determined and displayed in a window  124 . This status may be displayed both as a thermometer bar as shown and through text of how many records of the total records have been written into the main program section  54  of the flash memory  50 . A percentage of memory programmed may also be displayed in text in window  124 . 
     Thus, the exemplary screen image of  FIG. 6  will indicate to the individual through window  124  when programming is complete. In the present embodiment, the baud rate for communicating the selected main program to the memory  53  of the microcontroller  15  for programming is on the order of 9600 baud. Accordingly, at eight bits per byte, the programming of the flash memory  50  at this rate will be approximately three and a half minutes. Of course, at a higher communication baud rate, the programming time will be reduced. Thus, the programming time is only limited by the rate at which the flash memory  50  may be programmed which is on the order of a byte per thirty microseconds, for example. 
     When programming of the flash memory  50  with the selected main program file is completed, then the boot program may be re-executed by the microcontroller  15  to check if the signature coded words were properly loaded into the last byte registers of each page of the main program section  54 . If all of the signature coded words are proper, then execution is diverted to the main program for operation of the wheelchair. Otherwise, the boot program will again enter into the wait loop and wait for reprogramming instructions. 
     A flowchart of an exemplary boot program suitable for use in the embodiment described in connection with  FIG. 2  is depicted in  FIG. 5 . Referring to  FIGS. 5 , as the microcontroller  15  is powered up, the exemplary boot program starts execution at block B 1 . In the successive block B 2 , the boot program initializes certain of the microcontroller registers to configure or set up the microcontroller  15  for a particular application. In block B 4 , the boot program accesses the contents from the last byte registers of the seven pages of the main program loaded in the flash memory  50  (see  FIG. 4 ). In decision block B 6 , the accessed word of each page is compared with its respective code word CW 1 –CW 7 , and if all of the accessed words are correct, program execution is continued at block B 8  wherein the main program is initialized and started. 
     During the execution of the main program as represented by block B 10 , the serial port of the microcontroller  15  into which the serial cable  20  is coupled is polled or monitored for programming commands. If data is determined to be present at the serial port, then in block B 12 , the data is read into the microcontroller  15  and analyzed in block B 14 . If in block B 14 , it is determined that the data is a command from the PC  70  to update or reprogram the main program of the flash memory  50 , then program execution is diverted to the erase and load program of the boot programs starting at block B 20 . Otherwise, program execution continues in the main program of block B 10 . The erase and load program is also initiated at block B 20  if it is determined in block B 6  that any of the accessed words from the pages of the main program in the flash memory  50  is mismatched with its respective code word CW 1 –CW 7 . 
     In the boot programs, the erase and load program starts at block  20  wherein the receive baud rate of the serial port of the microcontroller  15  is increased to 9600 baud, for example. Thereafter, in block B 22 , the program waits to receive serial command data from the PC  70 . As shown in the flowchart, the combination of blocks B 22 –B 28  constitute a wait loop which is continuously executed until data is received. When data is received at the serial port of the microcontroller  15 , the received data is analyzed by the program in decisional blocks B 24 , B 26  and B 28 . If the data is determined in block B 24  to be an erase page X command, where X may be any integer from 1 to 7, for example, then the contents of page X of the main program is erased by the instructions of block B 30 . When the erasure of the page contents is complete, data representative of erasure completion is sent back over the cable  20  to the PC  70  by the instructions of block B 32 . Thereafter, program execution is diverted back to block B 22  awaiting receipt of the next data or command from the PC  70 . 
     If the data is not an erasure command, but rather a record or load new data command, then it is identified by block B 26 . In the present embodiment, when new data is to be loaded into the main program of the flash memory  50 , the first byte of a serial string of data bytes contains the character “S” and the second byte contains the numeral “2”. Accordingly, when “S” and then “2” are identified in the first and second bytes of the byte string in decisional block B 26 , then a record buffer of memory  53  is cleared in block  34  and a record enable flag is set true in block B 36 . 
     With the record enable flag set true, decision block B 28  diverts program execution to block B 38  wherein each of the subsequent characters of the string of data words are added to the record buffer. In the present embodiment, the serially received string of data words are in a standard ASCII format wherein a byte of data comprises two ASCII character bytes. That is, the first character byte contains the first four bits of the data byte and the second character byte contains the last four bits of the data byte. For this example, each string of data comprises 128 ASCII character bytes followed by one or more bytes of check sum error code. Also, contained within the data word string is a starting address of a main program portion of the flash memory into which the data string is to be loaded. The string of data from the PC  70  continues to be received by the microcontroller  15  and added to the buffer memory until the buffer is fully loaded as determined by block B 40 . 
     Thereafter, the check sum error code of the data string is analyzed by the instructions of block B 42 . If it is determined in block B 42  that the there is an error in transmission of the instant data stream, then a data word representing bad record data sent is transmitted back to PC  70  over the cable  20  by the instructions of block B 44  and the record enable flag is set false in block B 46 . Program execution is then returned to block B 22 . If the check sum error code is determined to be correct by block B 42 , then in block B 48  the main program section of the flash memory is loaded with the buffered string of data starting at the address specified in the data string. When the loading of data into the main program section of the flash memory is complete, data representative of programming complete is transmitted by block B 50  over the serial cable  20  to the PC  70  and the record enable flag is set false in block B 46 . 
     The foregoing described process for reprogramming the main program of the flash memory  50  will continue for a multiplicity of data string transmissions from the PC  70  to the microcontroller  15  until the main program is updated or reprogramming is complete. Thereafter, the boot program will be executed starting at block B 2 . 
     While the present invention has been described herein above in connection with one or more embodiments, it is understood that such descriptions are provided merely by way of example. Accordingly, the present invention should not be limited by any of the foregoing described embodiments, but rather construed in breadth and broad scope in accordance with the recitation of the claims appended hereto.

Technology Classification (CPC): 6