The present invention relates to a source driver (particularly, a digital driver) which is provided in a display device.
Patent Document 1 discloses one example of the arrangement of a digital driver which is used in a display device.
In this arrangement, each of the circuit blocks acquires, from D0 through D2, 3-bit data to be supplied to one corresponding data signal line, in response to a pulse signal (1st latch pulse signal) transmitted from a corresponding DEF in a shift register. Then, each of the circuit blocks carries out DA conversion on the 3-bit data in response to a pulse signal (2nd latch pulse signal) transmitted from an LP line, and outputs, to a corresponding one of the data signal lines (S1, S2, . . . ), an analog signal potential thus obtained.
Also, Patent Document 1 discloses another example of the arrangement of a digital driver.
In this arrangement, one horizontal period (a period constituted by the first period to the fourth period) is divided into four, and one circuit block is shared with the four data signal lines.
In the first period, each of the circuit blocks acquires, from D0 through D2, 3-bit data to be supplied to a corresponding one of the data signal line (S1, S5, . . . ), in response to a pulse signal (1st latch pulse signal) transmitted from a corresponding DEF in a shift register. Then, each of the circuit blocks carries out DA conversion on the 3-bit data in response to a pulse signal (2nd latch pulse signal) transmitted from an LPa line or an LPb line, and outputs, to a corresponding one of the data signal lines (S1, S5, . . . ), an analog signal potential thus obtained. In the second period which starts subsequently, each of the circuit blocks acquires, from D0 through D2, 3-bit data to be supplied to a corresponding one of the data signal lines (S2, S3, . . . ), in response to a pulse signal (1st latch pulse signal) transmitted from the corresponding DEF in the shift register. Then, each of the circuit blocks carries out DA conversion on the 3-bit data in response to a pulse signal (2nd latch pulse signal) transmitted from the LPa line or the LPb line, and outputs, to a corresponding one of the data signal lines (S2, S6, . . . ), an analog signal potential thus obtained. In the third period and the fourth period, this process is carried out in a similar manner.
[Patent Document 1]
Japanese Unexamined Patent Application Publication, Tokukai, No. 2003-58133 (published on Feb. 28, 2003)
The arrangement illustrated in
Also, in the arrangement illustrated in
The present invention was made in view of the foregoing problems, and an object of the present invention is to reduce the size of a driver without need for an external memory or an arithmetic circuit.
A display panel drive circuit according to the present invention includes: a plurality of circuit blocks each of which includes a former circuit and a latter circuit by which the former circuit is followed, and in each of which circuit blocks a signal is transmitted from the former circuit to the latter circuit; and inter-block shared wires which allow respective two of the circuit blocks adjacent to each other to be connected to each other, the signal of the respective two of the circuit blocks being transmitted in a time division manner, via a corresponding one of the inter-block shared wires.
In this arrangement, two circuit blocks adjacent to each other transmit the signal via the single inter-block shared wire in the time division manner. Sharing, with the circuit blocks, the wire to be used for transmitting a signal can reduce the number of wires. This makes it possible to reduce the size of the display panel drive circuit. Especially in a case where the display panel drive circuit is formed on a display panel monolithically, the decrease in the number of wires largely contributes to reduction of the size.
The display panel drive circuit may have such an arrangement that: the signal includes a plurality of video signals; the former circuit includes former signal circuits corresponding to the video signals, respectively; the latter circuit includes latter signal circuits corresponding to the video signals, respectively; each of the inter-block shared wires includes discriminatingly-shared wires (signal-by-signal shared wires) for the video signals; and the video signals are inputted to the former signal circuits, and are transmitted to the latter signal circuits via the discriminatingly-shared wires, respectively.
Also, the display panel drive circuit may further include switch circuits provided between (i) the former signal circuits and (ii) the discriminatingly-shared wires, respectively. In this case, the display panel drive circuit may have such an arrangement that the switch circuits, provided between (i) the former signal circuits belonging to odd-numbered ones of the circuit blocks and (ii) the discriminatingly-shared wires, respectively, are connected to a first control signal line; and the switch circuits, provided between (i) the former signal circuits belonging to even-numbered ones of the circuit blocks and (ii) the discriminatingly-shared wires, respectively, are connected to a second control signal line.
Also, the display panel drive circuit may further includes: a signal passing circuit which is provided for each of the circuit blocks; and an inter-signal shared wire which (i) is provided for each of the circuit blocks, and (ii) is connectable to all of the latter signal circuits belonging to said each of the circuit blocks, the signal from each of the latter signal circuits being transmitted to the signal passing circuit in the time division manner, via the inter-signal shared wire. This makes it possible to reduce the number of wires to be used between the latter signal circuits and the signal passing circuit, thereby further reducing the size of the display panel drive circuit. Also, the signal passing circuit may be a digital-analog converter (DAC) circuit. This makes it possible to reduce the number of DAC circuits.
Further, the display panel drive circuit may have such an arrangement that: each of the former signal circuits includes first latch circuits whose number is equal to the number of bits of a corresponding one of the video signals; each of the latter signal circuits includes second latch circuits whose number is equal to the number of bits of a corresponding one of the video signals; and each of the discriminatingly-shared wires includes wires whose number is equal to the number of bits of a corresponding one of the video signals. Also, latch pulse signals, to be supplied to the second latch circuits in the latter signal circuits, are supplied, respectively, via a wire which is not any of the discriminatingly-shared wires. In this case, it is preferable that: the latch pulse signals to be supplied to the second latch circuits in the latter signal circuits belonging to the odd-numbered ones of the circuit blocks are supplied, respectively, via the first control signal line; and the latch pulse signals to be supplied to the second latch circuits in the latter signal circuits belonging to the even-numbered ones of the circuit blocks are supplied, respectively, via the second control signal line.
A display panel drive circuit according to the present invention includes: a plurality of circuit blocks each of which includes a plurality of former signal circuits and latter signal circuits corresponding to the former signal circuits, respectively, and in each of which circuit blocks a signal is transmitted from the former signal circuits to corresponding ones of the latter signal circuits, respectively; and an intra-block shared wire which (i) is provided for each of the circuit blocks, and (ii) is connectable to all of the former signal circuits belonging to said each of the circuit blocks, the signal from each of the former signal circuits being transmitted in a time division manner, via the intra-block shared wire.
As such, transmitting the signal from the former signal circuits to the corresponding ones of the latter signal circuits via the intra-block shared wire in the time division manner reduces the number of wires to be used. This makes it possible to reduce the size of the display panel drive circuit. Especially in a case where a display panel drive circuit is formed on a display panel monolithically, the decrease in the number of wires largely contributes to reduction in the size.
The display panel drive circuit may have such an arrangement that: the signal includes a plurality of video signals; the former signal circuits are provided so as to correspond to the video signals, respectively; the latter signal circuits are provided so as to correspond to the video signals, respectively; and the video signals are inputted to the former signal circuits, and are transmitted to the latter signal circuits, respectively, via the intra-block shared wire.
Also, the display panel drive circuit may include switch circuits provided between the intra-block shared wire and the former signal circuits, respectively.
Further, the display panel drive circuit may have such an arrangement that: each of the former signal circuits includes first latch circuits whose number is equal to the number of bits of a corresponding one of the video signals; each of the latter signal circuits includes second latch circuits whose number is equal to the number of bits of a corresponding one of the video signals; and the intra-block shared wire includes wires whose number is equal to the number of bits of a corresponding one of the video signals. Also, latch pulse signals, to be supplied to the second latch circuits in the latter signal circuits, are supplied, respectively, via a wire which is not the intra-block shared wire. In this case, it is preferable for the display panel drive circuit to include control signal lines whose number is equal to the number of the video signals, and to have such an arrangement that a single control signal line is used for supplying (a) control signals to the switch circuits of the former signal circuits and (b) the latch pulse signals to the second latch circuits in the latter signal circuits corresponding to the former signal circuits, respectively.
A display device according to the present invention includes: a display panel; and the display panel drive circuit. In this case, the display panel and the display panel drive circuit may be formed monolithically. Examples of the display device may encompass a liquid crystal display device.
Thus, in a display panel drive circuit of the present invention, a signal is transmitted between two circuit blocks adjacent to each other via a single inter-block shared wire. Sharing, with circuit blocks, a wire used for transmitting a signal makes it possible to reduce the number of wires, thereby reducing the size of a display panel drive circuit.
10: Liquid crystal display device (Display device)
30: Display section
40: Gate driver
90, 95: Source drivers (Display panel drive circuits)
Q: Inter-block shared wire
HR, HG, HB: Discriminatingly-shared wires
CL: Inter-signal shared wire
N: Intra-block shared wire
T: Transmission switch block
iR, iG, iB: Switch circuits (for switching transmission)
MR, MG, MB: Transmission switch lines (Control signal lines)
Y1, Y2: Latch pulse lines (First and second control signal lines)
One embodiment of the present invention is described below with reference to
As illustrated in
Each of the signal processing blocks includes one flip-flop F (in a shift register), one circuit block g, one DAC, and one time division switch block W. Also, each of the signal processing blocks corresponds to three data signal lines SR, SG, and SB of the display section. The time division switch block W includes three analog switches ER, EG, and EB.
The circuit block g includes: a former circuit including three former latch blocks (former signal circuits) BR, BG, and BB lined up in the column direction; a latter circuit including three latter latch blocks (latter signal circuits) CR, CG, and CB lined up in the column direction; one transmission switch block T; one selection switch block K; and one inter-signal shared wire (6 bits) CL. In the digital driver 90, a plurality of circuit blocks are lined up in the row direction. Two circuit blocks adjacent to each other (e.g., the first circuit block and the second circuit block, and the third circuit block and the forth circuit block) have an inter-block shared wire Q between them. Further, the inter-block shared wire Q includes three discriminatingly-shared wires HR, HG, and HB.
The transmission switch block T includes three switch circuits iR, iG, and iB. The switch circuit iR contains 6 switching elements corresponding to HR; the switch circuit iG contains 6 switching elements corresponding to HG; and the switch circuit iB contains 6 switching elements corresponding to HB. (The 6 switching elements represent 6 bits.) That is, the transmission switch block T includes 18 switching elements for representing 18 bits. The selection switch block K includes three switch circuits JR, JG, and JB. The selection switch circuit JR contains 6 switching elements corresponding to the latter latch block CR; the selection switch circuit JG contains 6 switching elements corresponding to the latter latch block CG; and the selection switch circuit JB contains 6 switching elements corresponding to the latter latch block CB. (The 6 switching elements represent 6 bits.) That is, the selection switch block K includes 18 switching elements for representing 18 bits.
For example, the first signal processing block includes a flip flop F1, a circuit block g1, a DAC 1, and a time division switch block W1. The first signal processing block corresponds to three data signal lines SR1, SG1, and SB1. The time division switch block W1 includes three analog switches ER1, EG1, and EB1. The circuit block g1 includes: three former latch blocks BR1, BG1, and BB1; three latter latch blocks CR1, CG1, and CB1; a transmission switch block T1; a selection switch block K1; and an inter-signal shared wire CL1. The transmission switch block T1 includes three switch circuits iR1, iG1, and iB1, and the selection switch block K1 includes three switch circuits JR1, JG1, and JB1. Further, the circuit block g1 and the circuit block g2 adjacent to each other have an inter-block shared wire Q1 between them. The inter-block shared wire Q1 includes discriminatingly-shared wires HR1, HG1, and HB1.
As illustrated in
For example, the former latch block BR1 is connected to the flip flop F1 and the input signal line DR, and is connected to the latter latch block CR1 via the switch circuit iR1 and the discriminatingly-shared wire HR1 (6 bits). The latter latch block CR1 is connected to the DAC 1 via the switch circuit JR1 and the inter-signal shared wire CL1 (6 bits), and is connected to the latch pulse line Y1. A former latch block BR2 is connected to a flip flop F2 and the input signal line DR, and is connected to a latter latch block CR2 via a switch circuit iR2 and the discriminatingly-shared wire HR1 (6 bits). Further, the latter latch block CR2 is connected to a DAC 2 via a switch circuit JR2 and the inter-signal shared wire CL2 (6 bits), and is connected to the latch pulse line Y2.
Each of the former latch blocks includes six 1st (first) latch circuits lined up in the column direction, and each of the latter latch blocks includes six 2nd (second) latch circuits lined up in the column direction. For example, as illustrated in
The following describes the connection between the former latch block BR1 and the latter latch block CR1 more specifically. All of the six 1st latch circuits LR1 to LR6 belonging to the former latch block BR1 are connected to the corresponding flip flop F1. Also, the 1st latch circuits LR1 to LR6 are connected to the corresponding wires (1-bit wires) in the input signal line DR (6-bit wire), respectively. Further, the 1st latch circuits LR1 to LR6 are connected to the corresponding 2nd latch circuits in the latter latch block CR1, via the switch circuit iR1 and the corresponding wires in the discriminatingly-shared wire HR1 (6-bit wire), respectively. For example, the 1st latch circuit LR1 is connected to the 2nd latch circuit Lr1, via the switch circuit iR1 and the corresponding wire (1-bit wire) in the discriminatingly-shared wire HR1. Also, the 1st latch circuit LR6 is connected to the 2nd latch circuit Lr6, via the switch circuit iR1 and the corresponding wire (1-bit wire) in the discriminatingly-shared wire HR1. On the other hand, all of the 2nd latch circuits Lr1 to Lr6 are connected to the latch pulse line Y1, and are connected to the DAC 1 via the switch circuit JR1 and the corresponding wires (1-bit wires) in the inter-signal shared wire CL1, respectively. Further, the latch pulse line Y1 is connected to the switch circuit iR1.
Further, the following describes, with reference to
Thus, all of latter latch blocks belonging to odd-numbered circuit blocks are connected to the latch pulse line Y1, and all of latter latch blocks belonging to even-numbered circuit blocks are connected to the latch pulse line Y2. Further, transmission switch blocks (including three switch circuits) belonging to the odd-numbered circuit blocks are connected to the latch pulse line Y1, and transmission switch blocks (including three switch circuits) belonging to the even-numbered circuit blocks are connected to the latch pulse line Y2.
With this arrangement, when the latch pulse line Y1 is activated, the transmission switch block belonging to the odd-numbered circuit block turns on. Then, a latch pulse signal is inputted to the latter latch block in the circuit block, and a signal that has been latched by the former latch block in the odd-numbered circuit block is outputted from the latter latch block via the inter-block shared wire. Similarly, when the latch pulse line Y2 is activated, the transmission switch block belonging to the even-numbered circuit block turns on. Then, a latch pulse signal is inputted to the latter latch block in the circuit block, and a signal that has been latched by the former latch block in the even-numbered circuit block is outputted from the latter latch block via the inter-block shared wire.
Also, the three switch circuits (JR, JG, and JB) included in each of the selection switch blocks are connected to the corresponding switch control lines (PR, PG, and PB), respectively. That is, in a case of the selection switch block K1, the switch circuit JR1 is connected to the switch control line PR, the switch circuit JG1 is connected to the switch control line PG, and the switch circuit JB1 is connected to the switch control line PB.
Each of the DACs is connected to the three data signal lines via the corresponding time division switch block W. For example, the DAC 1 is connected to the data signal lines SR1, SG1 and SB1 via the time division switch block W1.
Further, the three analog switches (ER, EG, and EB) included in each of the time division switch blocks W are connected to the corresponding switch control lines (PR, PG, and PB), respectively. Also, the three analog switches (ER, EG, and EB) are connected to the corresponding data signal lines (SR, SG, and SB), respectively.
For example, the analog switch ER1 in the time division switch block W1 is connected to the switch control line PR and to the data signal line SR1, the analog switch EG1 is connected to the switch control line PG and to the data signal line SG1, and the analog switch EB1 is connected to the switch control line PB and to the data signal line SB1.
For example, a red (R) signal is processed by: the former latch block BR connected to the input signal line DR for red; the switch circuit iR; the discriminatingly-shared wire HR; the latter latch block CR1; the switch circuit JR; the DAC; and the analog switch ER. An analog signal thus obtained through the process is outputted to the data signal line SR for red. A green (G) signal and a blue (B) signal are processed in a similar manner. The DAC processes signals of three colors in a time division manner.
The flow of a process how a signal is processed in the digital driver 90 is illustrated in a timing chart in
At the timing when the state of an output pulse signal from F1 changes from “Low” to “High” (active), the former latch block BR1 latches the input signal R1; the former latch block BG1 latches the input signal G1; and the former latch block BB1 latches the input signal B1. Similarly, when the states of output pulse signals from F2, . . . , F640 change from “Low” to “High” one after another, the input signals (R2, G2, and B2), . . . , (R640, G640, and B640) are latched accordingly.
After the input signals (R1, G1, and B1), . . . , (R640, G640, and B640) are all latched, an output pulse signal from the latch pulse line Y1 becomes “High”. This turns on all of the transmission switch blocks connected to Y1 (i.e., the transmission switch blocks belonging to the odd-numbered circuit blocks). Then, all of the input signals (R1, G1, and B1), . . . , (R639, G639, and B639) which have been latched by the former latch blocks in the odd-numbered circuit blocks are outputted to the corresponding latter latch blocks via the corresponding inter-block shared wires Q (HR, HG, and HB), respectively. Subsequently, an output pulse signal from the latch pulse line Y2 becomes “High”. This turns on all of the transmission switch blocks connected to Y2 (i.e., the transmission switch blocks belonging to the even-numbered circuit blocks). Then, all of the input signals (R2, G2, and B2), . . . , (R640, G640, and B640) which have been latched by the former latch blocks in the even-numbered circuit blocks are outputted to the corresponding latter latch blocks via the corresponding inter-block shared wires Q (HR, HG, and HB), respectively.
Subsequently, at the timing when the state of an output pulse signal from the switch control line PR becomes “High”, all of the switch circuits (JR1, . . . ) connected to the switch control line PR turn on simultaneously, and the input signals (R1, . . . ) are inputted to the corresponding DACs (1, . . . ) via the corresponding inter-signal shared wires (CL1, . . . ), respectively. This converts the input signals (R1, . . . , R640) into analog signal potentials (Ra1, . . . , Ra640), respectively. Note that the switch control line PR is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse signal from the switch control line PR becomes “High”, all of the analog switches (ER1, . . . ) connected to the switch control line PR turn on simultaneously. This causes the signal potentials (Ra1, . . . Ra640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SR1, . . . , SR640), respectively.
Subsequently, at the timing when an output pulse signal from the switch control line PG becomes “High”, all of the switch circuits (JG 1, . . . ) connected to the switch control line PG turn on simultaneously, and the input signals (G1, . . . ) are inputted to the corresponding DACs (1, . . . ) via the corresponding inter-signal shared wires (CL1, . . . ), respectively. This converts the input signals (G1, . . . , G640) into analog signal potentials (Ga1, . . . , Ga640), respectively. Note that the switch control line PG is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse from the switch control line PG becomes “High”, all of the analog switches (EG1, . . . ) connected to the switch control line PG turn on simultaneously. This causes the signal potentials (Ga1, . . . Ga640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SG1, . . . , SG640), respectively.
Subsequently, at the timing when an output pulse signal from the switch control line PB becomes “High”, all of the switch circuits (JB1, . . . ) connected to the switch control line PB turn on simultaneously, and the input signals (B1, . . . ) are inputted to the corresponding DACs (1, . . . ), respectively. This converts the input signals (B1, . . . , B640) into analog signal potentials (Ba1, . . . , Ba640), respectively. Note that the switch control line PB is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse from the switch control line PB becomes “High”, all of the analog switches (EB1, . . . ) connected to the switch control line PB turn on simultaneously. This causes the signal potentials (Ba1, . . . Ba640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SB1, . . . , SB640), respectively.
Note that the digital driver 90 may be arranged as illustrated in
In the arrangement illustrated in
The circuit block g includes: three former latch blocks BR, BG, and BB lined up in the column direction; three latter latch blocks CR, CG, and CB lined up in the column direction; and one transmission switch block T.
Each of the latter latch blocks is connected to one corresponding data signal line via one corresponding DAC. For example, a latter latch block CR1 is connected to a data signal line SR1 via a DAC 1r, a latter latch block CG1 is connected to a data signal line SG1 via a DAC 1g, and a latter latch block CB1 is connected to a data signal line SB1 via a DAC 1b.
As illustrated in
A digital driver of the present invention may be arranged as illustrated in
Each of the signal processing blocks includes: one flip flop F (in a shift register); one circuit block g; one DAC; and one time division switch block W. Further, each of the signal processing blocks corresponds to three data signal lines SR, SG, and SB. The time division switch block W includes three analog switches ER, EG, and EB.
The circuit block g includes: a former circuit including three former latch blocks (former signal circuits) BR, BG, and BB lined up in the column direction; a latter circuit including three latter latch blocks (latter signal circuits) CR, CG, and CB lined up in the column direction; one transmission switch block T; an intra-block shared wire N; one selection switch block K; and one inter-signal shared wire (6 bits) CL.
In the digital driver 95, a plurality of circuit blocks are lined up in the row direction. The transmission switch block T includes three switch circuits iR, iG, and iB. The switch circuit iR contains 6 switching elements corresponding to HR; the switch circuit iG contains 6 switching elements corresponding to HG; and the switch circuit iB contains 6 switching elements corresponding to HB. (The 6 switching elements represent 6 bits.) That is, the transmission switch block T includes 18 switching elements for representing 18 bits. The selection switch block K includes three switch circuits JR, JG, and JB. The selection switch circuit JR contains 6 switching elements corresponding to the latter latch block CR; the selection switch circuit JG contains 6 switching elements corresponding to the latter latch block CG; and the selection switch circuit JB contains 6 switching elements corresponding to the latter latch block CB. (The 6 switching elements represent 6 bits.) That is, the selection switch block K includes 18 switching elements for representing 18 bits.
For example, the first signal processing block includes a flip flop F1, a circuit block g1, a DAC 1, and a time division switch block W1. Further, the first signal processing block corresponds to three data signal lines SR1, SG1, and SB1. The time division switch block W1 includes three analog switches ER1, EG1, and EB1. The circuit block g1 includes: three former latch blocks BR1, BG1, and BB1; three latter latch blocks CR1, CG1, and CB1; an intra-block shared wire N1; a transmission switch block T1; a selection switch block K1; and an inter-signal shared wire CL1. The transmission switch block T1 includes three switch circuits iR1, iG1, and iB1, and the selection switch block K1 includes three switch circuits JR1, JG1, and JB1.
As illustrated in
For example, the former latch block BR1 is connected to the flip flop F1 and the input signal line DR, and is connected to the latter latch block CR1 via the switch circuit iR1 and the intra-block shared wire N1 (6 bits). The latter latch block CR1 is connected to the DAC 1 via the switch circuit JR1 and the inter-signal shared wire CL1 (6 bits), and is connected to the transmission switch line MR. The transmission switch line MR is connected to the switch circuit iR1 (in the transmission switch block T1).
As described above, the latter latch block CR is connected to the transmission switch line MR, the latter latch block CG is connected to the transmission switch line MG, and the latter latch block CB is connected to the transmission switch line MB. Further, the switch circuit iR in the transmission switch block is connected to the transmission switch line MR, the switch circuit iG is connected to the transmission switch line MG, and the switch circuit iB is connected to the transmission switch line MB.
With this arrangement, when the transmission switch line MR is activated, the switch circuit iR in the transmission switch block turns on. Then, a latch pulse signal is inputted to the latter latch block CR, and a signal that has been latched by the latch block BR is outputted from the latter latch block CR via the intra-block shared wire N. Similarly, when the transmission switch line MG is activated, the switch circuit iG in the transmission switch block turns on. Then, a latch pulse signal is inputted to the latter latch block CG, and a signal that has been latched by the former latch block BG is outputted from the latter latch block CG via the intra-block shared wire N. Similarly, when the transmission switch line MB is activated, the switch circuit iB in the transmission switch block turns on. Then, a latch pulse signal is inputted to the latter latch block CB, and a signal that has been latched by the former latch block BB is outputted from the latter latch block CB via the intra-block shared wire N.
Further, the three switch circuits included in each of the selection switch blocks are connected to corresponding switch control lines, respectively. That is, the switch circuit JR1 in the selection switch block K1 is connected to the switch control line PR, the switch circuit JG1 is connected to the switch control line PG, and the switch circuit JB1 is connected to the switch control line PB.
Each of the DACs is connected to the three data signal lines via a corresponding time division switch block. For example, the DAC 1 is connected to the data signal lines SR1, SG1 and SB1 via the time division switch block W1.
Further, the three analog switches included in each of the time division switch blocks are connected to corresponding switch control lines, respectively. Also, the three analog switches are connected to corresponding data signal lines, respectively. For example, the analog switch ER1 in the time division switch block W1 is connected to the switch control line PR and to the data signal line SR1, the analog switch EG1 is connected to the switch control line PG and to the data signal line SG1, and the analog switch EB1 is connected to the switch control line PB and to the data signal line SB1.
Also, for example, a red (R) signal is processed by the former latch block BR1 connected to the input signal line DR for red, the switch circuit iR, the intra-block shared wire N1, the latter latch block CR1, the switch circuit JR1, and the analog switch ER1, each of which corresponds to the former latch block BR1. A green (G) signal and a blue (B) signal are processed in a similar manner. The DAC 1 processes signals of three colors in a time division manner.
The flow of signal processing in the digital driver 95 is illustrated in a timing chart illustrated in
At the timing when the state of an output pulse signal from F1 changes from “Low” to “High” (active), the former latch block BR1 latches the input signal R1; the former latch block BG1 latches the input signal G1; and the former latch block BB1 latches the input signal B1. Similarly, when the states of output pulse signals from F2, . . . , F640 change from “Low” to “High” one after another, the input signals (R2, G2, and B2), . . . , (R640, G640, and B640) are latched accordingly.
After the input signals (R1, G1, and B1) . . . (R640, G640, and B640) are all latched, an output pulse signal from the transmission switch line MR becomes “High”. This turns on all of the switch circuits iR connected to MR. Then, all of the input signals (R1 to R640) which have been latched by the former latch block BR are outputted to the latter latch block CR via the intra-block shared wire N. Subsequently, an output pulse signal from the transmission switch line MG becomes “High”. This turns on all of the switch circuits iG connected to MG. Then, all of the input signals (G1 to G640) which have been latched by the former latch block GR are outputted to the latter latch block CG via the intra-block shared wire N. Subsequently, an output pulse signal from the transmission switch line MB becomes “High”. This turns on all of the switch circuits iB connected to MB. Then, all of the input signals (G1 to G640) which have been latched by the former latch block BG are outputted to the latter latch block CB via the intra-block shared wire N.
Subsequently, at the timing when the state of an output pulse signal from the switch control line PR becomes “High”, all of the switch circuits (JR1, . . . ) connected to the switch control line PR turn on simultaneously, and the input signals (R1, . . . ) are inputted to the DACs (1, . . . ) via the corresponding inter-signal shared wires (CL1, . . . ), respectively. This converts the input signals (R1, . . . , R640) into analog signal potentials (Ra1, . . . , Ra640), respectively. Note that the switch control line PR is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse signal from the switch control line PR becomes “High”, all of the analog switches (ER1, . . . ) connected to the switch control line PR turn on simultaneously. This causes the signal potentials (Ra1, . . . Ra640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SR1, SR640), respectively.
Subsequently, at the timing when an output pulse signal from the switch control line PG becomes “High”, all of the switch circuits (JG1, . . . ) connected to the switch control line PG turn on simultaneously, and the input signals (G1, . . . ) are inputted to the DACs (1, . . . ) via the corresponding inter-signal shared wires (CL1, . . . ). This converts the input signals (G1, . . . , G640) into analog signal potentials (Ga1, . . . , Ga640), respectively. Note that the switch control line PG is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse signal from the switch control line PG becomes “High”, all of the analog switches (EG1, . . . ) connected to the switch control line PG turn on simultaneously. This causes the signal potentials (Ga1, . . . Ga640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SG1, . . . , SG640), respectively.
Subsequently, at the timing when an output pulse signal from the switch control line PB becomes “High”, all of the switch circuits (JB1, . . . ) connected to the switch control line PB turn on simultaneously, and the input signals (B1, . . . ) are inputted to the corresponding DACs (1, . . . ), respectively. This converts the input signals (B1, . . . , B640) into analog signal potentials (Ba1, . . . , Ba640), respectively. Note that the switch control line PB is also connected to the corresponding analog switch. Therefore, at the timing when the output pulse signal from the switch control line PB becomes “High”, all of the analog switches (EB1, . . . ) connected to the switch control line PB turn on simultaneously. This causes the signal potentials (Ba1, . . . Ba640) to be supplied, via the analog switches in the “on” state, to the corresponding data signal lines (SB1, . . . , SB640), respectively.
Thus, former latch blocks transmit a signal to corresponding latter latch blocks (BR→CR, BG→CG, BB→CB), respectively, via a single intra-block shared wire N in a time division manner. This makes it possible to reduce the number of wires to be used. In addition, the latter latch blocks (CR, CG, and CB) transmit a signal to a DAC via a single inter-signal shared wire CL in the time division manner. This makes it possible to reduce the number of wires to be used between latter latch blocks and a DAC. This makes it possible to reduce the size of a digital driver. Especially in a case where a digital driver is formed on a liquid crystal panel monolithically, the decrease in the number of wires largely contributes to the reduction of the size.
The invention being thus described, it will be obvious that the same way may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.
Industrial Applicability
A display panel drive circuit of the present invention is useful for a source driver (especially for a digital driver) which is used in devices such as a liquid crystal display device.
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2006-144713 | May 2006 | JP | national |
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PCT/JP2007/055647 | 3/20/2007 | WO | 00 | 1/5/2009 |
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WO2007/135805 | 11/29/2007 | WO | A |
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