Abstract:
Various systems and methods for implementing multi-display driver systems are disclosed. As one example, a display system is disclosed that includes a display driver, a processor, a computer readable medium, and a splitter device. The computer readable medium includes instructions executable by the processor to configure the display driver to provide a display output set for a virtual display. The splitter device is operable to receive at least a portion of a display output set, and to provide a first display output to drive a first display and a second display output to drive a second display based on the portion of the display output set.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    The present invention is related to display drivers, and more particularly to approaches for utilizing single display driver chips to drive multiple displays. 
         [0002]    Various chips have been developed to drive multiple displays.  FIG. 1  shows one exemplary multi-display driver  100 . Multi-display driver  100  includes two LCD drivers  110  that can each be separately programmed to drive respective displays  130 . Further, each of LCD drivers  110  may be designed to operate from its own memory buffer  120 . Such an approach allows for a great deal of flexibility in driving multiple displays as each of LCD drivers may be programmed to drive according to the particular characteristics of the display to be driven. Unfortunately, such an approach involves a product that may require substantially more area and cost than that required to drive only a single display. Further, such approaches do not allow for the use of existing single display drivers that may be both commonly available and relatively inexpensive. 
         [0003]    Thus, for at least the aforementioned reason, there exists a need in the art for advanced systems and methods for utilizing single display drivers to drive multiple displays. 
       BRIEF SUMMARY OF THE INVENTION 
       [0004]    The present invention is related to display drivers, and more particularly to approaches for utilizing single display driver chips to drive multiple displays. 
         [0005]    Various embodiments of the present invention provide multi-display driver systems. Such systems include a display driver, a processor, a computer readable medium, and a splitter device. The computer readable medium includes instructions executable by the processor to configure the display driver to provide a display output set for a virtual display. The splitter device is operable to receive at least a portion of a display output set, and to provide a first display output to drive a first display and a second display output to drive a second display based on the portion of the display output set. In some instances of the aforementioned embodiments, the display driver is capable of driving only a single display. Further, in some instances of the aforementioned embodiments, the display output set includes display data, and the splitter device includes a first FIFO memory for storing a first portion of the display data for the first display and a second FIFO memory for storing a second portion of the display data for the second display. 
         [0006]    In particular instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a single wide, double high display. In such instances, the display output set may include a virtual horizontal sync. The device splitter may assert a first horizontal sync for the first display upon a first assertion of the virtual horizontal sync and assert a second horizontal sync for the second display upon a second assertion of the virtual horizontal sync. 
         [0007]    In other particular instances of the aforementioned embodiments, the virtual display is a single wide, double high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a single wide, single high display. In such instances, the display output set may include a virtual vertical sync. The device splitter asserts a first vertical sync for the first display upon a first assertion of the virtual vertical sync and asserts a second vertical sync for the second display upon a second assertion of the virtual vertical sync. 
         [0008]    In yet other particular instances of the aforementioned embodiments, the display output set includes a virtual horizontal sync and a virtual vertical sync. The virtual display is a first virtual display, and the computer readable medium further includes instructions executable by the processor to: re-configure the display driver to provide the display output set for a second virtual display upon a preceding assertion of the virtual vertical sync; and re-configure the display driver to provide the display output set for the first virtual display upon a subsequent assertion of the virtual vertical sync. In such instances, the device splitter may assert a first vertical sync for the first display that corresponds to the subsequent assertion of the virtual vertical sync, and assert a second vertical sync for the second display that corresponds to the preceding assertion of the virtual vertical sync. 
         [0009]    In yet further particular instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a double wide, single high display. In such instances, the display output set may include a virtual display clock. The device splitter asserts a first display clock for the first display upon a preceding assertion of the virtual display clock and asserts a second display clock for the second display upon a subsequent assertion of the virtual display clock. 
         [0010]    Other embodiments of the present invention provide methods for driving multiple displays. Such methods include providing a display driver that is capable of driving only a single display. The display driver is configure to provide a display output set for a virtual display. Based on a portion of the display output set, a first display output is provided to drive a first display and a second display output is provided to drive a second display. In such cases, the first display content may be different from the second display content. 
         [0011]    In particular instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a single wide, double high display. The display output set includes a virtual horizontal sync. Providing the first display output includes asserting a first horizontal sync for the first display upon a first assertion of the virtual horizontal sync, and providing the second display output includes asserting a second horizontal sync for the second display upon a second assertion of the virtual horizontal sync. 
         [0012]    In other particular instances of the aforementioned embodiments, the virtual display is a single wide, double high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a single wide, single high display. The display output set includes a virtual vertical sync. Providing the first display output includes asserting a first vertical sync for the first display upon a first assertion of the virtual vertical sync, and providing the second display output includes asserting a second vertical sync for the second display upon a second assertion of the virtual vertical sync. 
         [0013]    In yet other particular instances of the aforementioned embodiments, the display output set includes a virtual horizontal sync and a virtual vertical sync, and two distinct virtual displays are supported. The methods further include: re-configuring the display driver to provide the display output set for a second virtual display upon a preceding assertion of the virtual vertical sync; and re-configuring the display driver to provide the display output set for the first virtual display upon a subsequent assertion of the virtual vertical sync. In such cases, providing the first display output includes asserting a first vertical sync for the first display that corresponds to the subsequent assertion of the virtual vertical sync; and providing the second display output includes asserting a second vertical sync for the second display that corresponds to the preceding assertion of the virtual vertical sync. 
         [0014]    In yet further particular instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a double wide, single high display. The display output set includes a virtual display clock. Providing the first display output includes asserting a first display clock for the first display upon a first assertion of the virtual display clock, and providing the second display output includes asserting a second display clock for the second display upon a subsequent assertion of the virtual display clock. 
         [0015]    Yet other embodiments of the present invention provide computer readable media that includes instructions executable by a processor to configure a display driver to provide a display output set for a virtual display. The display driver is capable of driving only a single display, and the display output is modifiable to drive at least a first display and a second display. In some instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a double wide, single high display. In such cases, the display output set includes a virtual display clock that is asserted to the first display on one cycle and to the second display on another cycle. In other instances of the aforementioned embodiments, the virtual display is a double wide, single high display, and configuring the display driver to provide the display output set for the virtual display includes configuring the display driver to drive a single wide, double high display. In such cases, the display output set includes a virtual horizontal sync; and the virtual horizontal sync is asserted to the first display on one cycle and to the second display on another cycle. 
         [0016]    This summary provides only a general outline of some embodiments according to the present invention. Many other objects, features, advantages and other embodiments of the present invention will become more fully apparent from the following detailed description, the appended claims and the accompanying drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0017]    A further understanding of the various embodiments of the present invention may be realized by reference to the figures which are described in remaining portions of the specification. In the figures, like reference numerals are used throughout several drawings to refer to similar components. In some instances, a sub-label consisting of a lower case letter is associated with a reference numeral to denote one of multiple similar components. When reference is made to a reference numeral without specification to an existing sub-label, it is intended to refer to all such multiple similar components. 
           [0018]      FIG. 1  depicts a prior art two display driver chip; 
           [0019]      FIG. 2  depicts an existing single display driver chip configured to drive two or more displays in accordance with some embodiments of the present invention; 
           [0020]      FIGS. 3   a - 3   b  depict a method in accordance with one or more embodiments of the present invention for utilizing an existing single display driver chip to drive two or more displays; 
           [0021]      FIGS. 4   a - 4   b  depict another method in accordance with some embodiments of the present invention for utilizing an existing single display driver chip to drive two or more displays; 
           [0022]      FIGS. 5   a - 5   b  depict yet another method in accordance with various embodiments of the present invention for utilizing an existing single display driver chip to drive two or more displays; 
           [0023]      FIGS. 6   a - 6   b  depict yet a further method in accordance with some embodiments of the present invention for utilizing an existing single display driver chip to drive two or more displays; and 
           [0024]      FIG. 7  depicts an existing single display driver chip configured to drive two or more displays via FIFO memories in accordance with other embodiments of the present invention. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0025]    The present invention is related to display drivers, and more particularly to approaches for utilizing single display driver chips to drive multiple displays. 
         [0026]    Turning to  FIG. 2 , a display system  200  including an existing single display driver chip  210  configured to drive two or more displays  245 ,  250  is depicted in accordance with some embodiments of the present invention. Single display driver chip  210  includes an LCD driver  215  and a memory buffer  220  as indicated by the dashed line. In some cases, a processor  230  and/or a memory  235  may also be incorporated on the same chip as LSC driver  215 . LCD driver  215  is programmable by processor  230  via a program interface  225 . Such programming may be accomplished through use of any of a number of programming approaches and interfaces known in the art and consistent with the requirements of LCD driver  215 , and may be accomplished by executing one or more instructions that are maintained in a memory  235 . Such instructions may be executable by processor  230  and/or LCD driver  215 , and may be, for example, software or firmware instructions. It should be noted that memory  235  may be any form or combination of computer readable media including, but not limited to, a hard disk drive, a random access memory, a flash memory, a removable magnetic storage media, a CD ROM, combinations of he aforementioned and/or the like. LCD driver  215  provides a display output set that includes both a display data portion and one or more timing signals. Such timing signals may include, but are not limited to, a horizontal sync signal, a vertical sync signal and a display clock. Based on the disclosure provided herein, one of ordinary skill in the art will recognize a variety of timing signals and display data that may be included in a display output set provided by LCD driver  215 . In different embodiments of the present invention, one portion  260  of the display output set is driven directly to both display  245  and display  250 . Another portion  270  of the display output set is driven indirectly to both display  245  and display  250  via a splitter logic circuit  240  also referred to herein as a splitter device. 
         [0027]    Display system  200  may be configured in a variety of novel ways to allow existing single display driver chip  210  to support two or more displays. Four different approaches are described below in relation to  FIGS. 4-6 , but it should be noted that other approaches may be possible in accordance with different embodiments of the present invention. Turning to  FIGS. 3   a - 3   b , a method in accordance with one or more embodiments of the present invention for utilizing an existing single display driver chip  210  to drive two or more displays is discussed. The method operates through defining a virtual display  300 . Virtual display  300  is a memory buffer that is defined to maintain a display memory for a first display  310 , and a display memory for a second display  320  virtually positioned horizontally next to first display  310 . Thus, where virtual display  300  is defined to be of a dimension X-width and Y-height, the memory buffer is a size 2X*Y. It should be noted that while virtual display  300  is shown as a rectangular memory area, that a linear or other memory area of the above mentioned size may be utilized in accordance with different embodiments of the present invention. Virtual display  300  is defined within memory buffer  220  as a double wide, single high display. 
         [0028]    In combination with virtual display  300 , LCD driver  215  is programmed by processor  230  to operate on a single wide, double high display. This causes LCD driver  215  to assert a horizontal sync at the half way point of each display line (i.e., addresses [x−1, 0], [x−1, 1] . . . [x−1,y]), and at the completion of each display line (i.e., addresses [2x, 0], [2x,  1 ] . . . [2x,y]). In such a configuration, the display data and the vertical sync timing signal are provided directly from LCD driver  215  to display  245  and display  250 . In contrast, the display clock and the horizontal sync timing signals from LCD driver  215  are provided indirectly to display  245  and display  250  via splitter logic circuit  240 . In operation, the display clock is passed to display  245  for the first half of the display line (i.e., addresses 0 to x−1) and gated from display  250  for the same period, and passed to display  250  for the second half of the display line (i.e., addresses x to 2x−1) and gated from display  245  for the same period. Similarly, horizontal syncs generated for the first half of the display line (i.e., addresses [x−1, y−1]) are passed to display  245 , and horizontal syncs generated for the second half of the display line (i.e., addresses [2x−1, y−1]) are passed to display  250 . 
         [0029]    It should be noted that some displays may effectively ignore the display clock when horizontal and vertical syncs are not received. For example, a display may clock in a defined number of display data (i.e., pixels) after reception of a horizontal sync, but ignore display data received in excess of the defined number. In such a circumstance, it may not be necessary to gate the display clock to the particular display. Alternatively, in some cases a display may ignore horizontal and vertical syncs that are not received with an active display clock. In such instances, by gating the display clock to a particular display it would not be necessary to also gate the horizontal and vertical syncs to the display. The aforementioned embodiments of the present invention may be described as having a device splitter that asserts a first horizontal sync for the first display upon a first assertion of the virtual horizontal sync and asserts a second horizontal sync for the second display upon a second assertion of the virtual horizontal sync. Such language is used in its broadest sense to mean any situation where a horizontal sync is alternated between multiple displays. Thus, this may include, but is not limited to: (1) asserting the horizontal sync to display  245  on one assertion of the horizontal sync provided by LCD driver  215  and not to display  250 , and asserting the horizontal sync to display  250  on a subsequent assertion of the horizontal sync provided by LCD driver  215  and not to display  245 ; (2) providing the display clock from LCD driver  215  to display  245  during one assertion of the horizontal sync and gating the display clock to display  250  during the same period, and providing the display clock from LCD driver  215  to display  250  during a subsequent assertion of the horizontal sync and gating the display clock to display  245  during the same period; and (3) gating both the horizontal sync and the display clock to display  245  during one period and not to display  250  during the same period, and gating both the horizontal sync and the display clock to display  250  during a subsequent period and not to display  245  during the same period. Based on the disclosure provided herein, one of ordinary skill in the art will recognize a variety of other approaches that may be used to assert a horizontal sync to one device and not the other, and then asserting the horizontal sync to the other display during a subsequent period. 
         [0030]    Turning to  FIG. 3   b , a flow diagram  301  graphically displays the above described process. Following flow diagram  301 , memory buffer  220  is provisioned to hold a 2X*Y memory (block  306 ). This is the double wide, single high virtual display. In addition, LCD driver  215  is programmed to treat virtual display  300  as a unified single wide, double high display (block  311 ). The memory address to memory buffer  220  is reset to the beginning of the display memory for a first display  310  (block  316 ). Display data from the beginning address is then read from memory buffer  220  and provided to both display  245  and display  250  (blocks  321 ,  326 ). The display clock may be, however, only passed through to display  245  during access to display memory  310 , and only to display  250  during access to display memory  320 . It is then determined whether the address is the last address in a line of virtual display  300  (i.e., 2x−1) (block  331 ). Where it is determined that the address is the last address in the line (block  331 ), it is determined whether the address is the last address of virtual display  300  (i.e., 2x−1,y−1) (block  346 ). Where the address is the last address of virtual display  300  (block  346 ), the vertical sync from LCD driver  215  is passed to both display  245  and display  250 ; the horizontal sync is passed from LCD driver  215  by splitter logic circuit  240  to display  250 ; and the memory address is reset (block  316 ). In contrast, where the address is not the last address of virtual display  300  (i.e., the x address is at a maximum, but the y address is not) (block  346 ), the horizontal sync is passed from LCD driver  215  by splitter logic circuit  240  to display  245  (block  351 ), the address is incremented (block  361 ), and the next display data is read from memory buffer  220  (block  321 ). 
         [0031]    Alternatively, where it is determined that the address is not the last address in the line (block  331 ), it is determined whether the address is the mid-address in the line (i.e., x−1) (block  336 ). Where it is determined that the address is the mid-address in the line (block  336 ), the horizontal sync is passed from LCD driver  215  by splitter logic circuit  240  to display  250  (block  341 ), the address is incremented (block  361 ), and the next display data is read from memory buffer  220  (block  321 ). In contrast, where it is determined that the address is not the mid-address in the line (block  336 ), the address is incremented (block  361 ), and the next display data is read from memory buffer  220  (block  321 ). 
         [0032]    As just some of the advantages of the embodiments discussed in relation to  FIGS. 3   a - 3   b , LCD driver  215  treats virtual display  300  as one large screen in memory, and provides a relatively simple implementation. It should be noted that the display clock is an Nx clock for a given display refresh rate where N represents the number of displays driven. In some cases, splitter logic circuit  240  may include buffers that may be used to re-time display data and/or timing signals to provide desired setup and hold times in relation to the display clock. 
         [0033]    Turning to  FIGS. 4   a - 4   b , another method in accordance with some embodiments of the present invention for utilizing existing single display driver chip  210  to drive two or more displays is discussed. The method operates through defining a virtual display  400 . Virtual display  400  is a memory buffer that is defined to maintain a display memory for a first display  410 , and a display memory for a second display  420  virtually positioned vertically next to first display  410 . Thus, where virtual display  400  is defined to be of a dimension X-width and Y-height, the memory buffer is a size X*2Y. It should be noted that while virtual display  400  is shown as a rectangular memory area, that a linear or other memory area of the above mentioned size may be utilized in accordance with different embodiments of the present invention. Virtual display  400  is defined within memory buffer  220  as a single wide, double high display. 
         [0034]    In combination with virtual display  400 , LCD driver  215  is programmed by processor  230  to operate on a double buffered single wide, single high displays. This causes LCD driver  215  to assert a horizontal sync at the end of each display line (i.e., addresses x), and to assert a vertical sync at the end of each of the double buffers (i.e., addresses [x−1, y−1] and [x−1, 2y−1]). In such a configuration, the display data and the horizontal sync timing signal are provided directly from LCD driver  215  to display  245  and display  250 . In contrast, the display clock and the vertical sync timing signals from LCD driver  215  are provided indirectly to display  245  and display  250  via splitter logic circuit  240 . In operation, the display clock is passed to display  245  while addresses associated display memory  410  are accessed and gated from display  250  for the same period, and passed to display  250  while addresses associated display memory  420  are accessed and gated from display  245  for the same period. Similarly, a vertical sync generated for the end of display memory  410  (i.e., address [x−1, y−1]) is passed to display  245 , and a vertical sync generated for the end of display memory  410  (i.e., address [x−1, y−1]) is passed to display  250 . 
         [0035]    Again, it should be noted that some displays may effectively ignore the display clock when horizontal and vertical syncs are not received. For example, a display may clock in a defined number of display data (i.e., pixels) after reception of a horizontal sync, but ignore display data received in excess of the defined number. In such a circumstance, it may not be necessary to gate the display clock to the particular display. Alternatively, in some cases a display may ignore horizontal and vertical syncs that are not received with an active display clock. In such instances, by gating the display clock to a particular display it would not be necessary to also gate the horizontal and vertical syncs to the display. The aforementioned embodiments of the present invention may be described as having a device splitter that asserts a first vertical sync for the first display upon a first assertion of the virtual vertical sync and asserts a second vertical sync for the second display upon a second assertion of the virtual vertical sync. Such language is used in its broadest sense to mean any situation where a vertical sync is alternated between multiple displays. Thus, this may include, but is not limited to: (1) asserting the vertical sync to display  245  on one assertion of the vertical sync provided by LCD driver  215  and not to display  250 , and asserting the vertical sync to display  250  on a subsequent assertion of the vertical sync provided by LCD driver  215  and not to display  245 ; (2) providing the display clock from LCD driver  215  to display  245  during one assertion of the vertical sync and gating the display clock to display  250  during the same period, and providing the display clock from LCD driver  215  to display  250  during a subsequent assertion of the vertical sync and gating the display clock to display  245  during the same period; and (3) gating both the vertical sync and the display clock to display  245  during one period and not to display  250  during the same period, and gating both the vertical sync and the display clock to display  250  during a subsequent period and not to display  245  during the same period. Based on the disclosure provided herein, one of ordinary skill in the art will recognize a variety of other approaches that may be used to assert a vertical sync to one device and not the other, and then asserting the vertical sync to the other display during a subsequent period. 
         [0036]    Turning to  FIG. 4   b , a flow diagram  401  graphically displays the above described process. Following flow diagram  401 , memory buffer  220  is provisioned to hold a double buffered X*Y memory (i.e., X*2Y) (block  406 ). This is a single wide, double high virtual display. In addition, LCD driver  215  is programmed to treat virtual display  400  as a double buffered single wide, single high display (block  411 ). The memory address to memory buffer  220  is reset to the beginning of display memory  410  (block  416 ). Display data from the beginning address is then read from memory buffer  220  and provided to both display  245  and display  250  (blocks  421 ,  426 ). The display clock is, however, only passed through to display  245  during access to display memory  410  and only to display  250  during access to display memory  250 . It is then determined whether the address is the last address in a line of virtual display  300  (i.e., x−1) (block  431 ). Where it is determined that the address is not the last address in a line (block  431 ), the address is incremented (block  471 ), and the next display data is read from memory buffer  220  (block  421 ). Where it is determined that the address is the last address in the line (block  431 ), it is determined whether the address is the last address of display memory  410  (block  436 ). Where it is determined that the address is the last address of display memory  410  (block  436 ), both a horizontal sync and a vertical sync is applied to display  245  (block  456 ), the address is incremented (block  471 ), and the next display data is read from memory buffer  220  (block  421 ). Alternatively, where it is determined that the address is not the last address of display memory  410  (block  436 ), it is determined whether the address is within display memory  410  or display memory  420  (i.e., whether the address is less than y−1) (block  441 ). Where it is determined that the address is within display memory  410 , a horizontal sync is asserted to display  245  (block  461 ), the address is incremented (block  471 ), and the next display data is read from memory buffer  220  (block  421 ). Alternatively, where it is determined that the address is not within display memory  410  (block  441 ), it is determined whether the address is the last address in display memory  420  (i.e., address 2y) (block  446 ). Where it is determined that the address is the last (block  446 ), a horizontal sync and a vertical sync are asserted to display  250  (block  451 ), the address is reset (block  416 ), and the next display data is read from memory buffer  220  (block  421 ). Alternatively, where it is determined that the address is not the last address in display memory  420  (block  446 ), a horizontal sync is asserted to display  250  (block  466 ), the address is incremented (block  471 ), and the next display data is read from memory buffer  220  (block  421 ). 
         [0037]    As just some of the advantages of the embodiments discussed in relation to  FIGS. 4   a - 4   b , LCD driver  215  treats virtual display  400  as one large screen in memory, and provides a relatively simple implementation. It should be noted that the display clock is an Nx clock for a given display refresh rate where N represents the number of displays driven. In some cases, splitter logic circuit  240  may include buffers that may be used to re-time display data and/or timing signals to provide desired setup and hold times in relation to the display clock. 
         [0038]    Turning to  FIGS. 5   a - 5   b , yet another method in accordance with some embodiments of the present invention for utilizing existing single display driver chip  210  to drive two or more displays is discussed. The method operates through defining a first virtual display  500  and a second virtual display  510 . Virtual display  500  is a memory buffer that is defined to maintain a display memory for a first display  505 , and a display memory for a second display  515 . Both virtual display  500  and virtual display  510  may be maintained in the same memory buffer. It should be noted that while virtual displays  500 ,  510  are shown as a rectangular memory areas, that a linear or other memory area of the above mentioned size may be utilized in accordance with different embodiments of the present invention. Virtual display  500  and virtual display  510  are defined within memory buffer  220 . 
         [0039]    In combination with virtual displays  500 ,  510 , LCD driver  215  is repeatedly re-programmed by processor  230  to operate on distinct displays. This causes LCD driver  215  to assert horizontal syncs and vertical syncs tailored for the respective displays. In such a configuration, the display data is provided directly from LCD driver  215  to display  245  and display  250 . In contrast, the display clock, the vertical sync, and the horizontal sync timing signals from LCD driver  215  are provided indirectly to display  245  and display  250  via splitter logic circuit  240 . In operation, the display clock, the horizontal sync and the vertical sync are passed to display  245  while addresses associated display memory  505  are accessed and gated from display  250  for the same period, and passed to display  250  while addresses associated display memory  515  are accessed and gated from display  245  for the same period. 
         [0040]    Turning to  FIG. 5   b , a flow diagram  501  graphically displays the above described process. Following flow diagram  501 , memory buffer  220  is provisioned to hold two distinct memory buffers (block  406 ). These are virtual displays  500 ,  510 . LCD driver  215  is programmed to drive a display of the same size as virtual display  500  (block  511 ), and the memory address is reset (block  516 ). While programmed to drive virtual display  500 , the display clock is provided to display  245 , and gated from display  250 . Display data is read from the memory (block  521 ) and provided to both display  245  and display  250  (block  526 ). It is then determined if the address corresponds to the last address in a display line of virtual display  500  (i.e., (x−1) 1 ) (block  531 ). Where the address does not correspond to the last address in a display line of virtual display  500  (block  531 ), the address is incremented (block  546 ), and the next data is read from memory buffer  220  (block  521 ). Of note, since the controller is being reprogrammed, each screen may have a buffer at an independent address. Further, the sizes and color depths of the two displays may also be different. Alternatively, where it is determined that the address does correspond to the last address in a display line of virtual display  500  (block  531 ), it is additionally determined whether the address corresponds to the last address in virtual display  500  (block  536 ). Where the address does not correspond to the last address in virtual display  500  (block  536 ), a horizontal sync is asserted to display  245  (block  541 ), the address is incremented (block  546 ), and the next data is read from memory buffer  220  (block  521 ). 
         [0041]    Where the address does correspond to the last address in virtual display  500  (block  536 ), a horizontal sync and a vertical sync are asserted to display  245  (block  551 ), and LCD driver  215  is re-programmed programmed to drive a display of the same size as virtual display  510  (block  556 ), and the memory address is reset (block  561 ). While programmed to drive virtual display  510 , the display clock is provided to display  250 , and gated from display  245 . Display data is read from the memory (block  566 ) and provided to both display  245  and display  250  (block  571 ). It is then determined if the address corresponds to the last address in a display line of virtual display  510  (i.e., (x−1) 2 ) (block  576 ). Where the address does not correspond to the last address in a display line of virtual display  510  (block  576 ), the address is incremented (block  591 ), and the next data is read from memory buffer  220  (block  566 ). Alternatively, where it is determined that the address does correspond to the last address in a display line of virtual display  510  (block  576 ), it is additionally determined whether the address corresponds to the last address in virtual display  510  (block  581 ). Where the address does not correspond to the last address in virtual display  510  (block  581 ), a horizontal sync is asserted to display  250  (block  586 ), the address is incremented (block  591 ), and the next data is read from memory buffer  220  (block  566 ). 
         [0042]    Where the address does correspond to the last address in virtual display  510  (block  581 ), a horizontal sync and a vertical sync are asserted to display  250  (block  596 ), and LCD driver  215  is re-programmed programmed to drive a display of the same size as virtual display  500  (block  511 ), and the memory address is reset (block  516 ). The process of re-programming LCD driver  215  may be accomplished during a vertical sync period of the particular displays. Such an approach allows for driving two displays with different characteristics. 
         [0043]    As just some of the advantages of the embodiments discussed in relation to  FIGS. 5   a - 5   b , LCD driver  215  is capable of displays with different characteristics including, but not limited to, display size and display clock rate. In such embodiments, both displays are treated as distinct virtual displays in memory. It should be noted that the display clock is approximately an Nx clock for a given display refresh rate where the number of driven displays is N. In particular cases, the display clock may be N 1 +N 2  and the two displays sizes may be very different. In some cases, a smaller display may require slower clocks than a larger display. It may turn out that the wall clock time is about equivalent to Nx, but two distinct clock frequencies will be required to drive the displays (one frequency for each display). In some cases, splitter logic circuit  240  may include buffers that may be used to re-time display data and/or timing signals to provide desired setup and hold times in relation to the display clock. 
         [0044]    Turning to  FIGS. 6   a - 6   b , yet a further method in accordance with one or more embodiments of the present invention for utilizing an existing single display driver chip  210  to drive two or more displays is discussed. The method operates through defining a virtual display  600 . Virtual display  600  is a memory buffer that is defined to maintain a display memory for double wide, single high display where data destined for two different displays are interleaved. In one particular embodiment of the present invention, the data destined for the two different displays is interleaved on a pixel by pixel basis. Based on the disclosure provided herein, one of ordinary skill in the art will recognize a variety of other approaches to interleaving that may be used in accordance with different embodiments of the present invention. 
         [0045]    In combination with virtual display  600 , LCD driver  215  is programmed by processor  230  to operate on a double wide, single high display. This causes LCD driver  215  to assert a horizontal sync at the end of each display line (i.e., addresses [x−1, 0], [x−1, 1] . . . [x−1,y−1]). In such a configuration, the display data, horizontal sync and the vertical sync timing signal are provided directly from LCD driver  215  to display  245  and display  250 . In contrast, the display clock is provided indirectly to display  245  and display  250  via splitter logic circuit  240 . In operation, the display clock is divided by two with one cycle of the divided display clock being passed to display  245 , and the other cycle of the display clock being passed to display  250 . 
         [0046]    Turning to  FIG. 6   b , a flow diagram  601  graphically displays the above described process. Following flow diagram  601 , memory buffer  220  is provisioned to hold a 2X*Y memory (block  606 ). This is the double wide, single high virtual display. In addition, LCD driver  215  is programmed to treat virtual display  600  as a unified double wide, single high display (block  611 ). The memory address to memory buffer  220  is reset to the beginning of virtual display  600  (block  616 ). Display data from the beginning address is then read from memory buffer  220  and provided to both display  245  and display  250  (blocks  621 ,  626 ). The display clock is, however, provided on an alternating basis to display  245  and then to display  250 . Thus, for example, the divided display clock is provided to display  245  in association with one display data, to display  250  in association with a succeeding display data, back to display  245  in association with the next succeeding display data, and then back to display  250  in association with the next succeeding display data. 
         [0047]    It is determined whether the address is the last address in the line (i.e., address 2x−1) (block  631 ). Where it is determined that the address is not the last address in the line (block  631 ), the address is incremented (block  636 ) and the next display data is read from memory buffer  220  (block  621 ). In contrast, where it is determined that the address is the last address in the line (block  631 ), it is determined whether the address is also the last address of virtual display  600  (i.e., 2−1x, y−1) (block  641 ). Where the address is not the last address of virtual display  600  (block  641 ), the horizontal sync is passed from LCD driver  215  to both display  245  and display  250  (block  646 ), the address is incremented (block  636 ), and the next display data is read from memory buffer  220  (block  621 ). Alternatively, where it is determined that the address is the last address of virtual display  600  (block  641 ), the vertical sync and the horizontal sync from LCD driver  215  are passed to both display  245  and display  250  (block  651 ), and the memory address is reset (block  616 ). 
         [0048]    As just some of the advantages of the embodiments discussed in relation to  FIGS. 6   a - 6   b , only a 1x display clock is provided to both displays. It should be noted that special graphics software may be used to interleave the data into virtual display  600 . In some cases, splitter logic circuit  240  may include buffers that may be used to re-time display data and/or timing signals to provide desired setup and hold times in relation to the display clock. 
         [0049]    It should be noted that in each of the aforementioned embodiments, the display data is provided directly to multiple displays. In some cases, this can resulting problematic setup and hold issues in relation to clocking the display data in to the recipient displays. Thus, some embodiments of the present invention utilize buffers to re-time the display data (e.g., performing line caching) provided to the respective displays. Turning to  FIG. 7 , a display system  700  including an existing single display driver chip  710  configured to drive two or more displays  745 ,  750  is shown in accordance with other embodiments of the present invention. Single display driver chip  710  includes an LCD driver  715  and a memory buffer  720  as indicated by the dashed line. LCD driver  715  is programmable by a processor  730  via a program interface  725 . Such programming may be accomplished through use of programming approach known in the art and consistent with LCD driver  715 , and may be accomplished by executing one or more instructions that are maintained in a memory  735 . Such instructions may be executable by processor  730  and/or LCD driver  715 , and may be, for example, software or firmware instructions. It should be noted that memory  235  may be any form or combination of computer readable media including, but not limited to, a hard disk drive, a random access memory, a flash memory, a removable magnetic storage media, combinations of he aforementioned and/or the like. LCD driver  715  provides a display output set that includes both a display data portion and one or more timing signals. Such timing signals may include, but is not limited to, a horizontal sync signal, a vertical sync signal and a display clock. Based on the disclosure provided herein, one of ordinary skill in the art will recognize a variety of timing signals and display data that may be included in a display output set provided by LCD driver  715 . In different embodiments of the present invention, one portion  760  of the display output set is driven to both display  745  and display  750  via respective FIFO memories  792 ,  794 . Another portion  770  of the display output set is driven indirectly through FIFO memories  792 ,  794  via a splitter logic circuit  740 . FIFO memories  792 ,  794  may be used to re-time signals from LCD driver  715  to displays  745 ,  750  as is known in the art. In contrast to that known in the art, one or more of the timing signals from LCD driver  715  may be reformed from a single display format produced by LCD driver  715  to a multiple display format consistent with that discussed above in relation to  FIGS. 3-6 . 
         [0050]    In conclusion, the present invention provides novel systems, devices, methods and arrangements for driving a display. While detailed descriptions of one or more embodiments of the invention have been given above, various alternatives, modifications, and equivalents will be apparent to those skilled in the art without varying from the spirit of the invention. Therefore, the above description should not be taken as limiting the scope of the invention, which is defined by the appended claims.