Abstract:
The present invention relates to a source driver circuit ( 200 ) for driving a thin film transistor liquid crystal display (TFT-LCD) panel. The source driver circuit ( 200 ) provides several different operating modes for the driver to lower the power consumption of a TFT-LCD module while still providing a wide analog voltage range to the liquid crystal display elements. A mode signal (MODE) switches the driver from gray scale to standby mode wherein the internal resistive digital to analog converter ( 202 ), decoder/output voltage drivers ( 210 ) and output buffer amplifiers ( 212 ) are powered down. In addition, only the most significant bit of data corresponding to red, green and blue are transferred to a sample and hold register ( 206, 208 ). Output cells ( 216 ), substituting for the decoder/output voltage drivers, receive one-bit data from hold registers ( 208 ) and provide voltage at the output of the driver circuit ( 200 ).

Description:
This application claims the benefit of provisional application No. 60/250,523 filed Nov. 30, 2000. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to a signal driver circuit for a liquid crystal display (LCD), and, more particularly, to a dual mode thin film transistor liquid crystal display (TFT-LCD) source driver circuit having low power consumption. 
     BACKGROUND OF THE INVENTION 
     Due to the increased demands for data, handheld communication and portable electronics equipment, such as radios, cellular and cordless telephones, pagers, personal digital assistants (PDAs) and the like, must display greater amounts of information. Equipment must provide displays which feature visual messages that include graphics and printed information as well as a means to access and manipulate such messages. Accordingly, equipment must provide displays that accommodate text and icon information, as well as graphic and video data. Most circuitry used to implement these and other features expend relatively large amounts of power. As a result, power consumption is a major concern for many handheld communication and portable electronics manufacturers. 
     Conventional liquid crystal displays (LCDs) provide these features using two sheets of polarizing material having a liquid crystal solution between the two, such that when an electric current passes through the liquid, the crystals align to block or pass light. Each crystal, therefore, acts like a switch, either allowing light to pass or blocking light. 
     Source driver circuits are commonly employed with liquid crystal displays. The driver circuit typically accepts digital video data as an input and provides an analog voltage output to each particular LCD pixel column. Generally, each column in the LCD must be uniquely addressed by a signal or column driver and given the proper analog voltage in order to achieve the desired transmissivity (i.e., the desired shade of gray or color). Moreover, it is desirable that the output voltage range of a driver circuit be wide to allow for a high pixel contrast ratio. 
     For color LCDs, each pixel is composed of 3 sub-pixel elements representing the primary colors of red, green and blue. For example, a color VGA panel having a resolution of 640 columns×480 rows of uniquely addressable pixels will have 3×640 columns, or 1920 columns. Typically, the signal driver circuit has one driver output for each column. Thus, controlling an LCD panel requires a large number of driver outputs that consume considerable circuit area and power. Since this large number of circuitry size impacts power consumption, it is desirable to provide stages of operation in which the operation of each driver circuit is suspended. 
     Conventionally, there are two modes of operation: standby and gray scale mode. There are two types of standby mode where operation of parts of the source driver is suspended. The first type of standby mode powers down all of the internal circuitry with the exception of some input signal detection circuitry. Given this mode, however, the driver provides no output signal. The second type of standby mode powers down some of the internal circuitry during normal operation of the circuit to save power, not altering the overall system behavior. In gray scale mode, a full color display is present at the LCD providing up to 262144 colors. Since it is common for the communications equipment to remain in standby mode or text mode, where only text or icon display on the panel, it is not necessary to display full color display quality. 
     An approach to lower power consumption may include the use of a color super-twisted nematic liquid crystal display (STN-LCD). Although this implementation provides the greatest benefit, there exists slow display response time. In addition, using STN-LCD makes it difficult to generate high resolution colors. Both of these problems contribute to the complexity of displaying real time video or graphic information. 
     Another approach to lower power consumption may include the use of color LCD displays using the thin film transistor (TFT) technology which produce color images that are as sharp as traditional CRT displays. The TFT-LCD is a type of LCD flat-panel display screen, in which each pixel is controlled by one to four transistors. Conventional, TFT-LCDs can provide higher display response time and high resolution colors, but the power consumption is ten times that of STN-LCD. As a further limitation to the TFT-LCD implementation, the light transmission curve shown in FIG. 4 illustrates that the conventional TFT-LCD source driver is useful during a limited range of the voltages. 
     Thus, there exists a need for a dual mode TFT-LCD source driver circuit having low power consumption that is operable in response to a large range of voltages having at least one type of standby mode where operation of a portion of the driver circuit is suspended to lower power consumption such that the LCD is still capable of providing text, icon, graphic and video information on the display without using the full scale of colors available in the gray scale mode. 
     SUMMARY OF THE INVENTION 
     To address the above-discussed deficiencies of the dual mode thin film transistor liquid crystal display source driver circuit, the present invention teaches dual mode thin film transistor liquid crystal display source driver circuit having low power consumption. A first embodiment of the source driver circuit including a data inputs which connect to sample registers. An N-bit shift register containing N is the uniquely addressable channels couples to the sample registers. The input data is indicative of an image to be displayed on the LCD. Hold registers couple to the sample registers to store the sampled data. The hold register receives a transfer signal to determine when the data from the sample register should be transferred to the hold register. A resister string can provide up to 64 voltage levels for example which couple to a set of decoder cells that are programmable to decode the input data to select respective output voltage levels. Output cells couple between the hold register a set of driver outputs. A set of switches connect each respective decoder cell to the driver outputs. Both the set of switches and output cells couple to receive a mode signal, such that two modes of operation exists. In the first mode, when each switch is closed, the output cells are bypassed and, in the second mode, when each switch is open, the decoder cells are bypassed. This provides for a gray scale mode having full color display resolution and a standby mode that decreases the amount of power dissipated yet presents voltage output for the LCD to provide text, icon, graphic and video data. 
     In an alternative embodiment, latch circuits are employed which vary the level of voltage output during the standby mode. Thus, video displays may be programmed to have a specified resolution while still conserving power. The latch circuits may couple between the sample registers and the hold registers or between the hold registers and the output cells. 
     Advantages of this design include but are not limited to dual mode thin film transistor liquid crystal display source driver circuit having low power consumption. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following description taken in conjunction with the accompanying drawings in which like reference numbers indicate like features and wherein: 
     FIG. 1 is a block diagram of a known embodiment of TFT-LCD source driver; 
     FIG. 2 is a block diagram of a first embodiment of a dual mode TFT-LCD source driver circuit in the gray scale mode in accordance with the present invention; 
     FIG. 3 is a block diagram of a first embodiment of a dual mode TFT-LCD source driver circuit in the standby mode in accordance with the present invention; 
     FIG. 4 is a voltage vs. light transmission diagram of the TFT-LCD source driver of FIG. 1; 
     FIG. 5 is a voltage vs. light transmission diagram of the dual mode TFT-LCD source driver of FIG. 2; 
     FIG. 6 is a circuit diagram of a resistive string voltage reference coupled to a ROM decoder output buffer cell; 
     FIG. 7 is a schematic of the output cell of FIGS. 3,  8 , and  12 ; 
     FIG. 8 is a block diagram of a second embodiment of a dual mode TFT-LCD source driver circuit in the gray scale mode in accordance with the present invention; 
     FIG. 9 is a schematic of a first embodiment of the latch circuit of FIGS. 8, and  12 ; 
     FIG. 10 is a schematic of a second embodiment of the latch circuit of FIGS. 8 and 12; 
     FIG. 11 is a schematic of a third embodiment of the latch circuit of FIGS. 8, and  12 ; and 
     FIG. 12 is a block diagram of a third embodiment of a dual mode TFT-LCD source driver circuit in the gray scale mode in accordance with the present invention. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     The present invention is best understood by comparison with the prior art. Hence this detailed description begins with a discussion of a known source driver  100  as illustrated in FIG.  1 . Driver  100  includes a shift register  104  which contains an N-bit shift register, where N is the number of uniquely addressable channels within the source driver. The shift register  104  is clocked with the CLK signal. The sample registers  106  receive serial video data from the serial video data bus to store channels of six-bit display data for one line period, enabling the internal resistive digital-to-analog converter (DAC)  102  coupled to the decoder/output voltage drivers  110  to use the display data from line time x while the next line of data (from line time x+1) is loaded into the sample registers  106 . The contents of the sample registers  106  are transferred to the hold registers  108  before being over-written with the next line of six-bit words of display data from the serial video data bus after a low to high transition of the transfer signal occurs at the end of line x+1. An internal resistor string  102  used for voltage dividing which may comprise a string of 64 resistors, produces 64 distinct voltage levels from the 9 voltage reference inputs. Linear voltage levels are generated between each pair of adjacent reference voltage inputs, utilizing the string of resistors between the reference voltages. Decoder/output voltage drivers  110  select the desired output voltage based upon the data in the hold register  108  for each of the channels. As the display data for line x+1 is loaded into the sample registers  106 , decoder/output voltage drivers  110  use the data for line x stored in the hold registers  108 . Each of the output voltage drivers  110  outputs one of the 64 analog voltages based upon the corresponding decode of the display data. 
     A detailed schematic of a known ROM decoder connect to a internal resistive DAC  102  may be found in FIG.  6 . As illustrated 8 reference voltages supplied across 64 resistors provide the voltage levels necessary for the ROM decoder to decode the six-bit data supplied from hold register  108 , where each ‘’ represents a transistor. 
     FIG. 2 displays a source driver circuit  200  in accordance with the present invention as it operates in the gray scale mode. Driver  200  includes a shift register  204  which contains an N-bit shift register, where N is the number of uniquely addressable channels within the source driver. The shift register  204  is clocked with the CLK signal. The sample registers  206  receive serial video data from the serial video data bus to store channels of six-bit display data for one line period, enabling the internal resistive digital-to-analog converter (DAC)  202  coupled to the decoder/output voltage drivers  210  to use the display data from line time x while the next line of data (from line time x+1) is loaded into the sample registers  206 . The contents of the sample registers  206  are transferred to the hold registers  208  before being over-written with the next line of six-bit words of display data from the serial video data bus after a low to high transition of the transfer signal occurs at the end of line x+1. An internal resistor string  202  used for voltage dividing which may comprise a string of 64 resistors, produces 64 distinct voltage levels from the 9 voltage reference inputs. Linear voltage levels are generated between each pair of adjacent reference voltage inputs, utilizing the string of resistors  202  between the reference voltages. Decoder/output voltage drivers  210  select the desired output voltage based upon the data in the hold register  208  for each of the channels. As the display data for line x+1 is loaded into the sample registers  206 , decoder/output voltage drivers  210  use the data for line x stored in the hold registers  208 . Each of the output voltage drivers  210  outputs one of the 64 analog voltages to output buffers  212  based upon the corresponding decode of the display data. Switches  214  are closed during gray scale mode to enable the full color resolution voltage levels to be provided at the LCD. 
     FIG. 3 displays a source driver circuit  200  in accordance with the present invention as it operates in the standby mode. Driver  200  includes a shift register  204  which contains an N-bit shift register, where N is the number of uniquely addressable channels within the source driver. The shift register  204  is clocked with the CLK signal. The sample registers  206  receive serial video data from the serial video data bus to store channels of six-bit display data for one line period, enabling the hold registers  208  to hold three-bit display data from line time x while the next line of data (from line time x+1) is loaded into the sample registers  206 . The contents of the sample registers  206  are transferred to the hold registers  208  before being over-written with the next line of six-bit words of display data from the serial video data bus after a low to high transition of the transfer signal occurs at the end of line x+1. Output cells  216  produces distinct voltage levels using 2 reference voltage reference inputs, a mode signal and data transferred by hold register  208 . Switches  214  are open during standby mode to power down the resistive string  202 , decoder/output voltage drivers  210  and buffers  212 . 
     FIG. 7 illustrates output cell  216  of FIGS. 2 and 3. The one-bit data signal HRO from each respective hold register connects to inverter  272  and NAND gate  274 . The mode signal MODE couples to the NAND gate  274  and AND gate  276 . NAND gate  274  connects to transistor  278  which is coupled between the output OUT and power supply VH. AND gate  276  connects to transistor  280  which couples between the output OUT and power supply rail VL. In operation, during gray scale mode the output is kept at high impedance. This occurs when the mode signal MODE is low. During standby mode, when the mode signal is high, voltage VL is provided at output OUT when the active bit of the hold register  208  is low. In the alternative, when the active bit of the hold register  208  is high, voltage VH is provided at the output OUT. 
     In accordance with the present invention in FIGS. 2 and 3, a TFT-LCD source driver circuit for driving source signal line of a liquid crystal display panel includes two driving modes: gray scale mode and monochrome mode. Gray scale modes applies selected voltage to source signal line. The selected voltage proportion to liquid crystal light transmission factor. Standby mode applies only two voltage levels to source signal line which drives the liquid crystal light transmission factor on 100% or 0% as shown in FIG.  5 . 
     There is a mode signal to select between gray scale mode and standby mode. In standby mode, digital to analog converter portion and output circuit is shut down. In addition, most of registers and latches are shut down as well. Only one bit of the register and latch data for each output channel is left operable. Thus, the line data connects to output stage from line register directly. Major power consumption portions are shutdown such that only the digital circuits are active. Logic gate transaction frequency and data line charge and discharge current of the sample register  206 , hold register  208  and output cell  216  may be used determine the source driver&#39;s total power consumption. 
     In order to save TFT-LCD power consumption, source driver in accordance with the present invention provides both a full color display (gray scale) mode and a standby display modes. With this solution, TFT-LCD could provide both full color and low power consumption for handheld or communication application i.e. PDA or mobile phone. During most of the time that the handheld communication device is in use, the device will be in standby mode which provides 8 colors at display quality (resolution in pixels). This mode is of substantial quality to display text and icons. When the need arises to display a video or more colors within an image, the TFT-LCD can switch to gray scale mode which provides more colors (i.e. 64 gray scale source driver produce 262144 colors). The TFT-LCD source driver in accordance with the present invention not only provides colors of display quality, but also saves power consumption in the monochrome and gray scale modes. 
     Signal driver circuit  200  shown in FIGS. 2 and 3 provides up to sixty four voltage levels on each of two hundred one LCD columns. It will be recognized, though that more or less voltages or columns may be utilized. Within signal driver  200 , decoder/output voltage drivers  24  are used to provide a specific voltage output to each column. 
     As shown in FIG. 3, the added switches  214  shut-down the analog circuits in the standby mode. The first power down mode includes powering down the internal resistive digital-to-analog converter (DAC)  202  where there will be no gamma reference voltage; thus, no power consumption. The second power down mode includes powering down the output buffer amplifiers  212  where the switches  214  control the switching of modes whether standby or gray scale. In standby mode, the two output transistors (not shown) may function as switches to control using a single bit of data to the driver output two different voltage levels. Such that the TFT-LCD displays only 100% brightness for the red, green and blue pixels. 
     FIG. 8 represents the standby mode of a second embodiment of a driver circuit  800  in accordance with the present invention. Driver  800  includes a shift register  802  which contains an N-bit shift register, where N is the number of uniquely addressable channels within the source driver  800 . The shift register  802  is clocked with the CLK signal. The sample registers  804  receive serial video data from the serial video data bus to store channels of six-bit display data for one line period, enabling the hold registers  806  to hold three-bit display data from line time x while the next line of data (from line time x+1) is loaded into the sample registers  804 . The contents of the sample registers  804  are transferred to the hold registers  806  before being over-written with the next line of six-bit words of display data from the serial video data bus after a low to high transition of the transfer signal occurs at the end of line x+1. Programmable latch circuits  807  couple between each respective hold register  806  and output cell  808  to decipher from the six-bit data transferred from hold register  807  and provide a one-bit signal to the output cell  808 . Output cells  808  produces distinct voltage levels using 2 reference voltage reference inputs, a mode signal and data transferred by latch circuit  807 . Switches  810  are open during standby mode to power down the resistive string, decoder/output voltage drivers and output buffers (not shown). 
     FIGS. 9,  10  and  11  illustrate a variety of ways in which the latch circuit  807  of FIG. 8 may be implemented. Specifically, in FIG. 9, OR gate  902  only provides the two most significant bits of six-bit data bit as output. Thus, pixel dot data corresponding to 16 and above will be represented at the LCD. In FIG. 10, OR gate  1002  only provides the three most significant bits of six-bit data bit as output. Thus, pixel dot data corresponding to 8 and above will be represented at the LCD. Moreover, in FIG. 11, AND gate  1106  and OR gates  1102  and  1104  only provides the four most significant bits of six-bit data bit as output. Thus, pixel dot data corresponding to 4 and above will be represented at the LCD. 
     FIG. 12 represents the standby mode of a third embodiment of a driver circuit  1200  in accordance with the present invention. Driver  1200  includes a shift register  1202  which contains an N-bit shift register, where N is the number of uniquely addressable channels within the source driver  1200 . The shift register  1202  is clocked with the CLK signal. The sample registers  1204  receive serial video data from the serial video data bus to store channels of six-bit display data for one line period, enabling the programmable latch circuits  1206  to decipher from the six-bit data transferred from sample register  1204  and provide a one-bit signal to the hold register  1208 . Hold registers  1208  will hold the one-bit display data from line time x while the next line of data (from line time x+1) is loaded into the sample registers  1204 . The contents of the sample registers  1204  are transferred through the latch circuits  1206  to the hold registers  1208  before being over-written with the next line of six-bit words of display data from the serial video data bus after a low to high transition of the transfer signal occurs at the end of line x+1. Output cells  1210  receive the one-bit data from hold register  1208  and produces distinct voltage levels using 2 reference voltage reference inputs, a mode signal and data transferred by hold register  1208 . Switches  810  are open during standby mode to power down the resistive string, decoder/output voltage drivers and output buffers (not shown). 
     The present invention finds application in video systems including digital still cameras, digital video cameras, digital video processing systems. 
     The reader&#39;s attention is directed to all papers and documents which are filed concurrently with this specification and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference. 
     All the features disclosed in this specification (including any accompany claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features. 
     The terms and expressions which have been employed in the foregoing specification are used therein as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding equivalents of the features shown and described or portions thereof, it being recognized that the scope of the invention is defined and limited only by the claims which follow.