The present application claims priority from Japanese patent application No. JP 2003-303480 filed on Aug. 27, 2003, the content of which is hereby incorporated by reference into this application.
The present invention relates to a semiconductor circuit. More particularly, it relates to a semiconductor circuit which constitutes a drive circuit for driving the pixels of an active panel-typed is play device using a liquid crystal panel, an organic electroluminescence panel, or the like.
An STN display device is so constituted that wiping is installed in two directions, x-axis direction (first direction) and y-axis direction (direction different from the first direction), throughout its display portion. When voltage is applied in the two directions, x and y, the liquid crystal at the intersection point is driven. An active matrix display device has an active element, such as thin film transistor (TFT), for each pixel, and in the display device, these active elements are switched and driven. These display devices are known as panel-type display device, such as liquid crystal display device and organic electroluminescence (organic EL) display device. The present invention is characterized in the circuitry of a semiconductor circuit which functions as a drive circuit for producing a screen display on a display panel, applied to these types of panel-type display devices. Also, the present invention is characterized in the circuit topology of a semiconductor integrated circuit chip wherein the above circuit is integrated.
For example, an active matrix liquid crystal display device using thin film transistors as active elements has a liquid crystal layer sealed between a pair of insulating substrates for which glass plates are favorably used. In its display area, a large number of pixels are formed in matrix arrangement. Outside the display area, a semiconductor integrated circuit chip as drive circuit is mounted. The thin film transistors constituting the individual pixels are led out of the display area through outgoing lines, and connected with this semiconductor integrated circuit chip. The thin film transistors disposed in the display area are connected with the, for example, 256 output terminals of gate drivers constituting the semiconductor integrated circuit chip through 256 gate lines in the scanning direction. The thin film transistors are selected by gate signals outputted through the output terminals, and the source lines of thin film transistors connected with the selected gate lines are supplied with indicative data. Thus, a screen display is produced.
In such an active matrix liquid crystal display device, liquid crystal driving voltage (gradation voltage) is applied to pixel electrodes for red (R), green (G), and blue (B) through thin film transistors. Therefore, no cross talk occurs between pixels, and a screen display with a large number of steps of gradation without cross talk can be produced.
The high breakdown voltage unit comprises level conversion circuits LS and a plurality (3×256 in this case) of high breakdown voltage inverters HV. Its output terminals (gate line terminals) GTM are connected with the gate lines of the display panel, and supply gate signals G1 to G256. The level conversion circuit LS converts inputted signals of 3V to 0V into as high a voltage level as 1.6V to −14V. Each of the gate line G1, G2, G3, G4, . . . , and G256 is provided with a gate driver GDR comprising a level conversion circuit LS and three high breakdown voltage inverters HV. The NOR gate NR is a gate for turning on and off a screen display on the display panel. During a non-display period when a full selection signal is inputted, the NOR gate NR discharges the electric charges in the pixels of the display portion.
The address signals of eight bits [0] to [7] are inputted as illustrated in
As illustrated in
The level conversion circuit LSa in the first stage comprises four PMOS transistors and two NMOS transistors, as illustrated in the figure. The level conversion circuit LSb in the second stage comprises two PMOS transistors and four NMOS transistors, as illustrated in the figure. The level conversion circuit LSc in the final stage comprises two PMOS transistors and two NMOS transistors, as illustrated in the figure. The level conversion circuit LSb in the second stage and the level conversion circuit LSc in the final stage are connected together through two inverters.
The gateless driver GLDR comprises level conversion circuits LS which level-convert externally inputted full selection signals of, for example, 3V to 0V, frame leading pulses, and shift register clocks into large-amplitude signals of, for example, 16V to −14V. The gateless driver outputs these level-converted signals to the lead-out terminals GTM of the display panel GIPNL.
Documents disclosing this type of prior art include Patent Document 1.
[Patent Document 1] Japanese Unexamined Patent Publication No. Hei 8(1996)-106272
In the above-mentioned constitution of gate driver, the high breakdown voltage unit includes the gate drivers GDR each comprising a level conversion circuit LS and three high breakdown voltage inverters HV. Such a gate driver GDR is provided for each of the gate lines G1, G2, G3, G4, . . . , and G256. As described referring to
The object of the present invention is to provide the following by solving the above problem associated with prior art: a semiconductor circuit with the reduced scale of circuitry and a semiconductor integrated circuit chip which is obtained by integrating this semiconductor circuit and enables chip size reduction.
The present invention is characterized in that the above problem is solved by adopting a two-stage decode method. This method uses a pre-decode circuit and post-decode circuits. The pre-decode circuit comprises a first decoder of the preceding stage which decodes arbitrary bits of an address signal and a second decoder of the preceding stage which decodes the remaining bits. The post-decode circuits which decode the decode output of each decoder in the pre-decode circuit.
The semiconductor circuit according to the present invention is a gate driver for supplying gate signals to the gate terminals of a display panel wherein a large number of pixels comprising active elements having the gate terminals are arranged in a matrix pattern. The semiconductor circuit is characterized in that it adopts the following means.
“Means 1 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor circuit comprises:
a pre-decode circuit comprising a first decoder of the preceding stage which decodes some bits of an address signal for selecting a gate terminal and a second decoder of the preceding stage which decodes the remaining bits of the address signal;
latch circuits which latch the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage;
level conversion circuits which shift the respective voltage levels of decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage, latched into the latch circuits, to the high voltage side; and
post-decode circuits which decode the outputs of the level conversion circuits.
“Means 2 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor circuit comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal and a second latch which latches the remaining bits;
a pre-decode circuit comprising a first decoder of the preceding stage which decodes the some bits latched into the first latch and a second decoder of the preceding stage which decodes the remaining bits latched into the second latch;
level conversion circuits which shift the respective voltage levels of the outputs of the first decoder of the preceding stage and the second decoder of the preceding stage to the high voltage side; and
post-decode circuits which decode the outputs of the first decoder of the preceding stage and the second decoder of the preceding stage, passed through the level conversion circuits.
“Means 3 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor circuit comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal and a second latch which latches the remaining bits;
level conversion circuits which shift the respective voltage levels of the some bits and the remaining bits latched into the first latch and the second latch to the high level side;
a pre-decoder circuit comprising a first decoder of the preceding stage which decodes the outputs of the first latch, passed through the level conversion circuit, and a second decoder of the preceding stage which decodes the outputs of the second latch; and
post-decode circuits which decode the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage.
“Means 4 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor circuit comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal and a second latch which latches the remaining bits;
level conversion circuits which shift the respective voltage levels of the some bits and the remaining bits, latched into the first latch and the second latch, to the high voltage side;
a pre-decode circuit comprising a first decoder of the preceding stage which decodes the output of the first latch passed through the level conversion circuits and a second decoder of the preceding stage which decodes the output of the second latch; and
post-decode circuits which decode the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage.
The post-decode circuit is constituted as a buffer-decoder which also functions as a buffer circuit placed between the pre-decode circuit and the gate terminals.
In the above-mentioned means 1 to 3, the waveform of output to the gate terminals varies between first reference voltage and second reference voltage whose level is lower than that of the first reference voltage. When it varies, the waveform has an inflection point between the first reference voltage and the second reference voltage.
The semiconductor integrated circuit chip according to the present invention supplies gate signals to the gate terminals of a display panel wherein a large number of pixels comprising active elements having the gate terminals and source terminals are arranged in a matrix pattern. Further, the semiconductor integrated circuit chip supplies indicative data to the source terminals. The semiconductor integrated circuit chip is characterized in that it adopts the following means: “Means 5 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor integrated circuit chip comprises a system interface circuit which is fed with parallel signals from an external signal source; an external display interface circuit which is fed with RGB indicative data; a timing generating circuit; a gradation voltage generating circuit; a graphic RAM; a source driver; and a gate driver which supplies gate signals to the gate terminals.
The gate driver comprises a pre-decode circuit comprising a first decoder of the preceding stage which decodes some bits of an address signal for selecting a gate terminal, and a second decoder of the preceding stage which decodes the remaining bits of the address signal; and post-decode circuits which decode the decode outputs of the pre-decode circuit.
“Means 6 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor integrated circuit chip comprises a system interface circuit which is fed with parallel signals from an external signal source; an external display interface circuit which is fed with RGB indicative data; a timing generating circuit; a gradation voltage generating circuit; a graphic RAM; a source driver; and a gate driver which supplies gate signals to the gate terminals.
The gate driver comprises:
a pre-decode circuit comprising a first decoder of the preceding stage which decodes some bits of an address signal for selecting gate terminals and a second decoder of the preceding stage which decodes the remaining bits of the address signal;
latch circuits which latch the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage;
level conversion circuits which shift the respective voltage levels of the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage, latched into the latch circuits, to the high voltage side; and
post-decode circuits which decode the outputs of the level conversion circuits.
“Means 7 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor integrated circuit chip comprises a system interface circuit which is fed with parallel signals from an external signal source; an external display interface circuit which is fed with RGB indicative data; a timing generating circuit; a gradation voltage generating circuit; a graphic RAM; a source driver; and a gate driver which supplies gate signals to the gate terminals.
The gate driver comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal, and a second latch which latches the remaining bits;
a pre-decode circuit comprising a first decoder of the preceding stage which decodes the some bits latched into the first latch and a second decoder of the preceding stage which decodes the remaining bits latched into the second latch;
level conversion circuits which shift the respective voltage levels of the outputs of the first decoder of the preceding stage and the second decoder of the preceding stage to the high voltage side; and
post decode circuits which decode the outputs of the first decoder of the preceding stage and the second decoder of the preceding stage, passed through the level conversion circuits.
“Means 8 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor integrated circuit chip comprises a system interface circuit which is fed with parallel signals from an external signal source; an external display interface circuit which is fed with RGB indicative data; a timing generating circuit; a gradation voltage generating circuit; a graphic RAM; a source driver; and a gate driver which supplies gate signals to the gate terminals.
The gate driver comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal, and a second latch which latches the remaining bits;
level conversion circuits which shift the respective voltage levels of the some bits and the remaining bits, latched into the first latch and the second latch, to the high voltage side;
a pre-decode circuit comprising a first decoder of the preceding stage which decodes the output of the first latch, passed through the level conversion circuit, and a second decoder of the preceding stage which decodes the output of the second latch; and
post-decode circuits which decode the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage.
“Means 9 for Implementing Semiconductor Circuit According to the Present Invention”
The semiconductor integrated circuit chip comprises a system interface circuit which is fed with parallel signals from an external signal source; an external display interface circuit which is fed with RGB indicative data; a timing generating circuit; a gradation voltage generating circuit; a graphic RAM; a source driver; and a gate driver which supplies gate signals to the gate terminals.
The gate driver comprises:
a latch circuit comprising a first latch which latches some bits of an address signal for selecting a gate terminal, and a second latch which latches the remaining bits;
level conversion circuits which shift the respective voltage levels of the some bits and the remaining bits, latched into the first latch and the second latch, to the high voltage side;
a pre-decode circuit comprising a first decoder of the preceding stage which decodes the output of the first latch, passed through the level conversion circuit, and a second decoder of the preceding stage which decodes the output of the second latch circuits; and
post decode circuits which decode the decode outputs of the first decoder of the preceding stage and the second decoder of the preceding stage. The post-decode circuit is constituted as a buffer-decoder which also functions as a buffer circuit placed between the pre-decode circuit and the gate terminals.
The semiconductor circuit according to the present invention is so constituted that a plurality of bits of an address signal are not decoded in a lump, but are decoded once (pre-decode) and then decoded again (post decode). Thus, the number of level conversion circuits is significantly reduced.
The present invention is not limited to the inventions according to the claims descried later, and, needless to add, it may be modified in various ways to the extent that the technical philosophy underlying it is not departed from.
a) and 17(b) are explanatory drawings for comparison.
a) and 18(b) are also explanatory drawings for comparison.
a) and 21(b) are schematic diagrams for comparison.
Referring to the drawings, the embodiments of the present invention will be described in detail below.
Part (one bit) of the eight bits [0] to [7] of the inputted address signal is decoded at the first decoder DCR-A of the preceding stage in the decoder DCR. Its decode outputs AD00 and AD01 are latched into latches LT, respectively. This latch is carried out with the timing of a latch clock. The remaining seven bits of the address signal are decoded at the second decoder DCR-B of the preceding stage in the decoder DCR to obtain decode outputs AU000, AU001, . . . , and AU127. These decode outputs are latched into the respective latches LT.
The decode output latched into each latch LT is inputted to the high breakdown voltage unit through a NOR gate NR. The range of voltage level of the latched decode outputs is, for example, 3V to 0V. A shift register may be used instead of the latch circuit.
In the high breakdown voltage unit, the decode outputs AD00 and AD01 for “one bit” decoded at the first decoder DCR-A of the preceding stage are converted into as high a voltage level as 16V to −14V through the level conversion circuits LS, respectively. Then, the decode outputs AD00 and AD01 are outputted through the high breakdown voltage inverters HV. The decode outputs AU000, AU001, . . . , and AU127 for “seven bits” respectively latched into the latches LT are converted into as high a voltage level as 16V to −14V through the level conversion circuits LS, respectively. Thereafter, the decode outputs AU000, AU001, . . . , and AU127 are inputted to the gate drivers GDR each comprising a high breakdown voltage NAND gate HND and a high breakdown voltage inverter HV.
The gate driver GDR is provided for each of the gate lines G1, G2, G3, G4, . . . , and G256. Either input of each of these high breakdown voltage NAND gates HND is fed with the level conversion output of the decode outputs AD00 and AD01 for “one bit.” As in
The pre-decode outputs AD00 and AD01 for bit “0” corresponding to “one bit” and the pre-decode outputs AU000, AU001, . . . , and AU127 for bits “1” to “7” corresponding to “seven bits” are level-shifted at the high breakdown voltage unit. Thereafter, the pre-decode outputs AU000, AU001, . . . , and AU127 for bits “1” to “7” are decoded again at the gate drivers GDR (post-decode). At this time, they are decoded together with the pre-decode outputs AD00 and AD00 for bit “0” corresponding to “one bit.” The post-decoded address data is respectively supplied as gate signals G1, G2, G3, . . . to the corresponding gate lines through the gate line terminals GTM.
As mentioned above, this embodiment is so constituted that: a plurality of bits of an address signal are not decoded in a lump. Instead, they are divided into two groups at an arbitrary bit, and the groups of bits are individually decoded (pre-decode). The outputs resulting from them are latched into latch circuits, and the latched outputs are level-converted and then decoded again (post-decode). Thus, the number of level conversion circuits is significantly reduced.
In this embodiment, two-stage decode is carried out. This method is such that the eights bits of an address signal are not decoded in a lump; instead, the bits are divided into one bit and seven bits, and pre-decoded; thereafter, the bits are level-converted and then post-decoded (full decode). Thus, the number of level conversion circuits can be reduced substantially in half from 256 to 130 (128+2). Two level conversion circuits are for one bit of an address signal, and 128 level conversion circuits are for seven bits of the address signal. However, high breakdown voltage NAND circuits HND for post-decode are added to the high breakdown voltage unit. Nevertheless, the number of level conversion circuits can be significantly reduced as compared with the constitution illustrated in
The one bit at which the bits of an address signal are divided may be arbitrary, but the highmost bit or lowmost bit is preferably selected with the facilitation of circuit constitution taken into account. To minimize the wire routing, lowest bit is suitable.
The two bits AD[0] and [1] of the address signal are decoded into decode outputs AD00 to AD03 by the first decoder DCR-A of the preceding stage, and the decode outputs AD00 to AD03 are latched into the latches LT, respectively. The latch is carried out with the timing of a latch clock. The remaining “seven bits” AD[2] to [7] of the address signal are decoded into decode outputs AU00 to AU63 by the second decoder DCR-B of the preceding stage, and the decode outputs AU00 to AU63 are latched into the latches LT, respectively. As in the first embodiment, thereafter, the outputs are fully decoded at the post-decoders, and supplied as gate signals G1, G2, G3, . . . to the corresponding gate lines through the gate line terminals GTM.
In this embodiment, the number of level conversion circuits LS can be reduced substantially to ¼ from 256 in
AD[0] latched into the first latch circuit LT-A is decoded by the first decoder DCR-A in the pre-decoder DCR, and AD[1] to [7] latched into the second latch circuit LT-B are decoded by the second decoder DCR-B. With respect to the other aspects, the constitution is the same as in
As mentioned above, this embodiment is so constituted that: a plurality of bits of an address signal are not decoded in a lump. Instead, they are divided into two groups at an arbitrary bit, and latched into a latch circuit. The latched groups of bits are respectively decoded (pre-decode). The outputs resulting from pre-decode are level-converted, and then decoded again (post-decode). Thus, the number of level conversion circuits is significantly reduced. The number of level conversion circuits can be reduced substantially in half from 256 in
The one bit at which the bits of an address signal are divided maybe arbitrary, but the highmost bit or lowmost bit is preferably selected with the facilitation of circuit constitution taken into account. To minimize the wire routing, lowest bit is suitable.
One bit AD[0] of an inputted address signal of eight bits [0] to [7] is latched into the first latch LT-A in the latch circuit LT, and the remaining seven bits AD[1] to [7] are latched into the second latch LT-B. AD[0] of the address signal latched into the first latch LT-A is decoded by the first decoder DCR-A in the pre-decoder DCR, and AD[1] to [7] of the address signal latched into the second latch LT-B are decoded by the second decoder DCR-B. The subsequent signal processing is the same as in
As mentioned above, this embodiment is so constituted that: a plurality of bits of an address signal are not decoded in a lump. Instead, they are divided into two groups at an arbitrary bit, and the groups of bits are latched into a latch circuit, respectively. The latched groups of bits are level-converted, and the output of the latch circuit is decoded (pre-decode) and then decoded again (post-decode). Thus, the number of level conversion circuits is significantly reduced. Since the level conversion circuits LS are placed in the stage preceding the decoder DCR, the number of them can be reduced to a number corresponding to the number of bits of the address signal. Therefore, the number of level conversion circuits can be further reduced than in the first, second, and third embodiments.
In this embodiment, four bits AD[0] to [3] of an address signal are latched into a first latch circuit LT-A, and the remaining four bits AD[4] to [7] of the address signal are latched into a second latch circuit LT-B. The output of the first latch circuit LT-A is provided with four level conversion circuits LS, and the output of the second latch circuit LT-B is provided with four level conversion circuits LS. A pre-decode circuit DCR is connected with the outputs of the two sets of the four level conversion circuits LS. The pre-decode circuit DCR comprises a first decoder DCR-A and a second decoder DCR-B, each of which corresponds to the four respective level conversion circuits LS. The outputs of the four respective level conversion circuits LS are inputted to the first decoder DCR-A and the second decoder DCR-B corresponding to the four respective level conversion circuits LS, and pre-decode there. With respect to the other aspect, including post-decoder, the constitution is the same as in
As mentioned above, this embodiment is so constituted that: a plurality of bits of an address signal are not decoded in a lump. Instead, they are divided into two groups at an arbitrary bit, and the groups of bits are latched into a latch circuit, respectively. The latched groups of bits are level-converted. The output of the latch circuit is decoded (pre-decode), and then decoded again (post-decode). Thus, the number of level conversion circuits is significantly reduced. Since the level conversion circuits LS are placed in the stage preceding the decoder DCR, the number of them can be reduced to a number corresponding to the number of bits of the address signal. Therefore, the number of level conversion circuits can be further reduced than in the first, second, and third embodiments. The number of elements of the pre-decoder circuit can be significantly reduced as compared with the constitution in
The output of the first decoder DCR-A in the pre-decoder DCR is inputted to the buffer-decoder drivers BDD through the respective high breakdown voltage NOR gates HNR. The buffer-decoder driver BDD comprises three high breakdown voltage inverters HV. The waveform inputted to each terminal corresponds to the waveform marked with the same symbol in
The output of the second decoder DCR-B in the pre-decoder DCR is inputted to the decoder-integrated gate driver D-GDR through a high breakdown voltage NOR gate HNR and two high breakdown voltage inverters HV. Each of the decoder-integrated gate drivers D-GDR corresponds to two gate lines.
A pre-decoded signal is inputted to the source terminal of the PMOS of the high breakdown voltage inverter HV constituting the decoder-integrated gate driver D-GDR. When the pre-decoded signal in the source terminal of the PMOS is brought into the low level, the output is also brought into the low level. However, at that time, the output is not completely brought into the low level. To cope with this, a NMOS transistor for holding level is added, as illustrated in
An example of operation will be taken. If all the bits AD of an address are at “0,” the output BDT00 of the buffer-decoder driver BDD is at the high level, and the output BDB00 is at the low level. The output BUB000 of the second decoder DCR-B is brought into the low level, the output to the gate line 1 is selected. If only bit [0] of the address is at “1,” BDB00 is at the low level and BDB00 is at the high level. As BDB00 is at the low level, G1 come to low level to flow current between the source terminal of the PMOS and the drain terminal of the PMOS. And when voltage difference between BUB00 and G1 becomes less or equal threshold voltage of PMOS, the PMOS becomes turn off and the G1 becomes floating level. However, the G1 is held by the NMOS transistor so as to hold level to the low level or the VGL level.
In this embodiment, the buffer circuit of the gate driver is provided with decode function. Then, the gate driver is caused to function as a post-decoder which uses control signals generated from pre-decode signals from the bits of the address signal. Thereby, the number of level conversion circuits is significantly reduced. The NAND circuits HND in the post-decoder circuits are obviated, and the packaging area can be reduced.
The circuit in
With the constitution in
The waveforms in
In this embodiment, the operation of the post-decoder can be checked by the inflection points in the waveform of output to the gate terminals.
a) and 17(b) are explanatory drawings for comparison of examples of the layout of integrated circuit chip.
The left halves of
In the embodiment of the present invention illustrated in
a) and 18(b) are explanatory drawings for comparison of another examples of the layout of integrated circuit chip.
In
Two sets of four bits of an address signal latched into the first latch LT-A and the second latch LT-B are level-converted through level conversion circuits LS, respectively, and inputted to a decoder DCR. The decoder DCR comprises a first decoder DCR-A and a second decoder DCR-B, each of which decodes four level-converted bits of the address signal. The outputs of the first decoder DCR-A and second decoder DCR-B are supplied to the terminals GTM connected with the gate lines of the display panel, through high breakdown voltage NOR gates HNR and high breakdown voltage inverters HV. Thus, in this embodiment, the shift registers SR in the panel GIPNL, required in the embodiments the present inventors previously invented, can be replaced with one NAND gate HND, and the area of the display panel can be reduced. Further, the number of level conversion circuits is significantly reduced, and the area of the semiconductor integrated circuit according to the present invention can be reduced.
a) and 21(b) are schematic diagrams for comparison of examples of the layer of integrated circuit chip.
As illustrated in
With respect to
In any of
In the aforesaid embodiments, a plurality of bits constituting an address signal are not decoded in a lump, but they are once decoded (pre-decode) and then decoded again (post-decode). With this constitution, the number of level conversion circuits is significantly reduced. Some bits of an address signal are decoded, and the remaining bits of the address signal are separately decoded. With this constitution, the area of the decoder can be reduced. All of gate drivers are not included in a high breakdown voltage unit, but they are divided into a high breakdown voltage unit and a low breakdown voltage unit. Thus, the power consumption and the packaging area can be reduced.
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