The present invention relates to an image display apparatus provided with a display panel in which a plurality of display devices are connected to one another by matrix wiring.
This kind of related art image display apparatus is disclosed in, for example, JP-A-8-248920. In this image display apparatus, a total of N×M cold cathode devices (N devices are arrayed in the row direction of a matrix and M devices are arrayed in the column direction of the same) are two-dimensionally arranged in matrix form, and the image display apparatus has multiple cathodes which include the N×M cold cathode devices connected to one another by matrix wiring with M-number of row wirings provided in the row direction and N-number of column wirings provided in the column direction (passive matrix structure).
In this image display apparatus, predetermined driving voltages are applied to both the row wirings and the column wirings to drive the cold cathode devices connected to both wirings to emit electrons, and electron beams are irradiated onto phosphors disposed in opposition to the multiple cathodes, thereby displaying an image.
In the case where a multiplicity of cold cathode devices connected by matrix wiring are to be driven, a method of driving a group of devices for one row of the matrix at the same time (a group of devices for one row are connected to one row wiring) is carried out.
Namely, a predetermined selecting potential is applied to one row wiring, while predetermined modulated potentials are respectively applied to only column wirings which are connected to driving targets among N-number of cold cathode devices connected to the one row wiring, whereby a plurality of devices for one row are controlled at the same time. Subsequently, all the rows are scanned in such a way that driving is switched from row to row, whereby a two-dimensional image is formed by making use of the afterimage phenomenon of vision (line sequential driving).
As compared with a method of performing scanning on a device-by-device basis, this method has the advantage that driving time to be allotted for each device can be made N times as long, whereby the luminance of the image display apparatus can be made high.
However, the N-number of cold cathode devices for one row are connected to one row wiring, and the respective cold cathode devices are connected to different positions of the one row wiring. For this reason, when cold cathode devices for one row are driven at the same time, the luminances of the individual devices become non-uniform under the influence of voltage drops due to wiring resistance.
These voltage drops are particularly remarkable in a selected row wiring into which a concentrated current flows during line sequential driving.
In addition, such a voltage drop is varied not only by a resistance value from a driving end of the row wiring to the position of the voltage drop, but also according to at which position a cold cathode device in a driven state is located. Accordingly, when compensation is to be performed, it is necessary to perform compensation according to image data.
To compensate for a luminance decrease caused by the voltage drop, JP-A-8-248920 discloses a construction which calculates the quantity of correction of image data and synthesizes the quantity of correction and the image data.
The related art construction will be described below with reference to
In addition, the present inventor discloses in JP-A-2002-229506 an example which suitably compensates for the influence of voltage drops by means of a more simple circuit construction. Although the detailed description provided in JP-A-2002-229506 is omitted herein, JP-A-2002-229506 discloses an image display apparatus which performs line sequential scanning of its display panel having wirings connected in matrix form. Furthermore, there is disclosed a construction which calculates and compensates for the quantities of voltage drops occurring in scanning wirings when modulation is being performed by means of voltage-amplitude modulation, through a reduced number of circuits.
JP-A-2002-229506 also has a description referring to a method of dividing the length of a scanning wiring into a plurality of blocks before the calculation of voltage drop quantities, calculating the voltage drop quantities of the respective blocks from the states of lighting of the respective blocks, and correcting the waveforms of driving pulses to be applied to a respective plurality of column wirings, by interpolating the voltage drop quantities of the respective blocks.
The present inventors have made further investigations and have discovered that a modulation method using both modulation of pulses in the voltage direction and modulation of pulses in the time direction as shown in
The reason for this is as follows:
(1) If a preferable number of gray scale levels for displaying an image are to be represented, the use of simple pulse-width modulation makes the clock frequency of pulse-width modulation excessively high; and
(2) If a preferable number of gray scale levels for displaying an image are to be represented, the use of simple amplitude modulation increases the number of bits of a D/A conversion circuit, so that the circuit scale becomes large.
However, investigations have not yet been made as to a method of compensating for the influence of the above-described voltage drops according to gray scale information on image data in the modulation method using both modulation of modulated pulses in the voltage direction and modulation of modulated pulses in the time direction.
Satisfactory investigations have not yet been made as to: in what order modulated pulses are to be increased in the above-described modulation method when input data for modulation means are increased for the purpose of compensating for voltage drops and suitably displaying an image.
An object of the invention is to provide an art which suitably compensates for the influence of voltage drops and obtains a preferable display image by using a modulation method employing both modulation of pulse width in the voltage direction and modulation of pulse width in the time direction.
Another object of the invention is to provide an image display apparatus which comprises:
image display devices arranged in matrix form, driven via a plurality of row wirings and column wirings, and used for forming an image;
scanning means for sequentially selecting and scanning the row wirings;
modulation means for outputting a modulated signal to be applied to the column wirings; and
voltage drop compensation means for calculating corrected image data for reducing an influence of voltage drops due to at least resistance components of the row wirings, with respect to image data,
wherein the modulated signal is a pulse-width modulated voltage signal having a plurality of voltage amplitude values,
the modulation means output a modulated signal in which a pulse width and/or a voltage amplitude value of the modulated signal are expanded on the basis of the corrected image data.
Preferred embodiments of the invention will be illustratively described below in detail with reference to the accompanying drawings. In the following description, unless otherwise specified, the scope of the invention is not to be construed to be limited to specific factors such as dimensions, materials, shapes or relative arrangements of individual constituent components of embodiments which will be described below.
As described above, an image display apparatus in which image display devices such as surface conduction electron-emitting devices are arranged in the form of a passive matrix structure has the problem that a display image is degraded by the influence of voltage drops on row wirings.
The first embodiment aims to suitably compensate for the influence of voltage drops due to wiring resistance in an image display apparatus employing a modulation system which modulates the voltage direction and the time direction of pulse width (amplitude and pulse-width modulations).
The general view and the electrical connection of a display panel which is an image display apparatus according to the invention are based on the construction described in JP-A-2002-229506, that is to say, a structure in which row wirings and column wirings are arranged in the form of a so-called passive matrix and image display devices are respectively disposed at the intersections of the row wirings and the column wirings (refer to
The characteristics of a surface conduction electron-emitting device which can be suitably used as one example of an image display device for the image display apparatus according to the invention will be described below.
(Characteristics of Surface Conduction Electron-Emitting Device)
The surface conduction electron-emitting device includes two electrodes and an electron-emitting part formed therebetween. As shown in
This surface conduction electron-emitting device has the following three characteristics as to the emission current Ie.
Firstly, when a voltage not lower than a certain voltage (called a threshold voltage Vth) is applied to the device, the emission current Ie increases sharply, whereas the emission current Ie is rarely detected in the case of a voltage lower than the threshold voltage Vth. Namely, the surface conduction electron-emitting device can be called a non-linear device having the threshold voltage Vth which is definite with respect to the emission current Ie.
Secondly, since the emission current Ie varies depending on the device driving voltage Vf applied to the device, the magnitude of the emission current Ie can be controlled by varying the device driving voltage Vf.
Thirdly, since the cold cathode device has a high-speed response, the emission time of the emission current Ie can be controlled by the application time of the device driving voltage Vf.
Because the surface conduction electron-emitting device has the above-described characteristics, the device can be suitably used in a display apparatus. For example, by using the first characteristic, the display apparatus can perform display while sequentially scanning its display screen. Namely, voltages not lower than the threshold voltage Vth are appropriately applied to devices which are being driven, according to a desired emission luminance, while voltages lower than the threshold voltage Vth are applied to devices which are placed in a non-selected state. The display apparatus can perform display while sequentially scanning the display screen by sequentially switching devices to be driven.
In addition, by using the second characteristic, the display apparatus can control the emission luminance of its phosphors according to the magnitude of the device driving voltage Vf to be applied to the devices, whereby it is possible to realize display of gray scale images and adjustment of image quality.
In addition, by using the third characteristic, the display apparatus can control the emission time of the phosphors according to the time for which to apply the device driving voltage Vf to the devices, whereby it is possible to realize display of gray scale images and adjustment of image quality.
Accordingly, the image display apparatus of the invention performs modulation for a display panel 1 by using both of the second and third characteristics.
The driving pulse shown in
The waveform shown in
In the amplitude direction of voltage, four voltages V1, V2, V3 and V4 (in the first embodiment, |V1|<|V2|<|V3|<|V4|, where ∥ represents an absolute value) are respectively shown according to different input values given to the modulation means.
The differences between the voltage amplitude values, i.e., |V2|−|V1|, |V3|−|V2| and |V4|−|V3|, are each hereinafter called one unit voltage.
The numbers shown in
For example, if the input data is 511 (decimal number), the voltage V2 is outputted during the 1st to 255th time slots and the voltage V1 is outputted during the 256th time slot (
Similarly, if the input data is 770 (decimal number), the voltage V4 is outputted during the 1st and 2nd time slots and the voltage V3 is outputted during the 3rd to 256th time slots (
According to the invention, in the image display apparatus which outputs a driving voltage waveform modulated in the time direction and in the voltage-amplitude direction on the basis of input data given to the modulation means that corresponds to image data, when compensation of voltage drops which will be described below is performed, the integral value of the amount of the compensation is increased by maintaining the method of forming this voltage waveform.
Namely, when the input data is to be increased by one unit as the compensation of the voltage drops, the time slot is first preferentially increased (increased by one unit time), and if the time slot is satisfied, the voltage amplitude value is increased by one unit voltage.
The waveform shown in
In the above-described example, the voltage amplitude direction are realized by switching four power sources, but this method is not construed to be particularly limitative.
The potential difference between any of the potentials V1, V2, V3 and V4 and a selecting voltage Vs which a scanning circuit outputs to a selected scanning wiring is set to be larger than the threshold voltage Vth shown in
The potential difference between any of the potentials V1, V2, V3 and V4 and a non-selecting voltage Vns which the scanning circuit outputs to a non-selected scanning wiring is set to be smaller than the threshold voltage Vth.
By setting operating points in this manner, it is possible to suitably perform modulation by the modulation method of the first embodiment.
A voltage drop compensation method according to the first embodiment will be described below.
(Voltage Drop Compensation Method)
When voltage drops are to be compensated for in the above-described modulation method, the quantities of voltage drops which actually occur needs to be calculated as a preparatory step.
To predict the quantity of a voltage drop to occur on the row wiring 1003, the present inventors have taken account of the following characteristics (1) to (3).
(1) The output waveform of the modulation means is a waveform which temporally varies as shown in
From this characteristic, in the first embodiment, the temporal variation of the quantity of a voltage drop which occurs during one horizontal scanning period is ignored, and compensation is performed on the basis of the quantity of a voltage drop which occurs averagely during one horizontal scanning period (the average quantity of a voltage drop during one horizontal scanning period is hereinafter called “effective voltage drop quantity”).
In addition, as the next approximation, the effective voltage drop quantity is calculated on the assumption that a voltage of effective amplitude value is applied which is obtained by averaging the temporal variations of modulated pulses applied to modulation wirings.
(2) In the Vf vs. If characteristic curve shown in
(3) Voltage drops which occur in row wirings selected when the device current If1, a device current If2, . . . , and a device current IfN are respectively made to flow in a column wiring 1, a column wiring 2, . . . , and a column wiring N satisfy a so-called principle of superposition, so that voltage drops which occur when the respective device currents are made to flow in the individual column wirings can be easily calculated as a superposed voltage drop quantity.
Therefore, in the first embodiment, the voltage drop quantity is calculated in accordance with the following steps.
First of all, input image data is converted to effective voltage values to be applied to the individual modulation wirings when the input image data is directly inputted to the modulation means.
Then, the effective voltage values are converted to the effective quantities of device currents which flow when the effective voltage values are applied to surface conduction electron-emitting devices on the selected column wirings.
Further, voltage drop quantities on the column wirings when the device currents are made to flow in the respective column wirings are calculated in accordance with the characteristic (3).
Further, the calculated voltage drop quantities are respectively added to the above-described effective voltage values to compensate for the same.
Further, the obtained voltage values are converted to modulation data which enables the average value of the amplitudes to become an effective voltage value to be obtained by addition, and the modulation data is inputted to the modulation means.
In
In addition, in
ΔV1=4/5×r×If1,
ΔV2=3/5×r×If1,
ΔV3=2/5×r×If1, and
ΔV4=1/5×r×If1. [Equations 1]
ΔV1=3/5r×If2,
ΔV2=6/5×r×If2,
ΔV3=4/5×r×If2, and
ΔV4=2/5×r×If2
ΔV1=2/5×r×If3,
ΔV2=4/5×r×If3,
ΔV3=6/5×r×If3, and
ΔV4=3/5×r×If3. [Equations 3]
ΔV1=1/5×r×If4
ΔV2=2/5×r×If4,
ΔV3=3/5×r×If4, and
ΔV4=4/5×r×If4. [Equations 4]
From the above-described characteristic (3), these equations 1 to 4 satisfy the principle of superposition, so that when the respective device currents If1 to If4 are injected into the column wirings 1 to 4, potentials occur at ΔV1 to ΔV4 according to Equation 5.
In the description of the first embodiment, reference has been made to a simple model including four column wirings. However, the present inventors have confirmed that the above-described law applies in principle to other cases where a far larger number of column wirings are used or the resistance values of wirings are not uniform, even though the constant and the like change.
The image display apparatus includes not smaller than 100 column wirings. However, even if the number of column wirings increases, the voltage drop quantities on selected column wirings can be calculated by repeating the above-described calculation method as to each of the column wirings.
In the case of a display panel having N number of column wirings, this calculation is performed as the matrix operation shown by Equation 6. However, to execute the operation of Equation 6 in synchronism during one horizontal scanning period, the number of calculations becomes extremely large so that large scale hardware is needed (an N×N product-sum operation needs to be performed by N times).
where aij(i=1 to N, j=1 to N) is a constant determined by the value of wiring resistance.
Accordingly, the present inventors adopt a method of calculating an approximate solution of a voltage drop quantity by means of a degenerate approximate model in order to simplify calculations.
Namely, as shown in
(1) N number of column wirings are grouped into four blocks (n=N/Block; Block=4).
(2) The sum of device currents in each of the blocks is made to flow into the center of the same.
(3) Nodes P1 to P5 are defined at boundary positions between the blocks, and the potential differences (voltage drop quantities) between the potentials of the nodes P1 to P5 and supply end potentials (Vs) of selected column wirings are respectively defined as ΔVN1 to ΔVN5 (the reason for this is to make it easy to calculate linear approximation which will be described later, because the nodes are defined at the boundary positions between the blocks).
(4) The value of the resistance between each adjacent one of the nodes is multiplied by n in terms of degeneration. ΔVN1 to ΔVN5 in the degenerate model shown in
where bij(i=1 to 5, j=1 to 4) is a constant determined by the value of wiring resistance, and IFB[J] (J=1, 2, . . . BLOCK) is the sum of current values IF[I] contained in the block J.
In the case of BLOCK=4 in this example, IFB[J] can be calculated as follows:
where n represents the number of column wirings contained in one block, and n=N/BLOCK=N/4.
The device current IF[I] (I=1, 2, . . . , N) in a certain column wiring can be found from the characteristic of
In addition, bij represents a potential produced at the i-th node when a unit current is injected into the j-th block, on the basis of the end portions of the row wiring. This bij is a constant determined by the value of wiring resistance, and can be calculated in accordance with Kirchhoff's laws.
Accordingly, by performing the calculation of Equation 7, it is possible to approximately find the values ΔVN1 to ΔVN5 of voltage drops at the nodes P1 to P5.
Then, in the first embodiment, the voltage drop quantity on the column wiring positioned between adjacent ones of the nodes is found by performing linear approximation with voltage drop quantities ΔVNk and ΔVNk+1 at the two adjacent nodes on the basis of Equation 9.
Since the positions of the respective nodes are set at the boundaries between the blocks as described above, there is a merit which enables a voltage drop quantity at a point between adjacent middle ones of the blocks to be easily linearly approximated even at a block positioned at either of extreme ends of the row wiring. Namely, it is possible to perform linear approximation at the extreme-end block more easily than to define a node between the middle ones of the blocks.
In the above example, the number of blocks is four, but it goes without saying that it is possible to reduce approximation error by increasing the number of blocks. Since the curve of the voltage drop occurring on the row wiring is a smooth curve, the practical problem of this approximation error due to linear approximation can be nearly solved by sufficiently increasing the number of blocks.
As the number of blocks, an optimum value may be selected in terms of the value of wiring resistance, the characteristics of surface conduction electron-emitting devices, modulated voltage, the number of column wirings, error caused by these factors, and the like.
As to the number of calculations, in the case where approximation is not performed, N number of product-sum operations must be repeated by N times. However, in the case where approximation is performed, as shown by the matrix operation of Equation 7, a product-sum operation needs only to be repeated by (BLOCK)×(BLOCK+1) times, whereby the number of calculations can be greatly reduced (in the above-described example, since BLOCK=4, 4×5=20 product-sum operations suffice). In general, this number of calculations can be executed within a period of time sufficiently shorter than one horizontal scanning period.
By adding the voltage drop quantities calculated in the above-described manner to modulated potentials to be applied to the column wirings and applying to the column wirings the modulated potentials which are offset by the added quantities, emission currents emitted from the respective surface conduction electron-emitting devices are prevented from being influenced by voltage drops on the row wirings.
Accordingly, by applying this compensation, it is possible to ameliorate the degradation of images due to the influence of voltage drops that has so far been a problem.
In addition, since calculations are performed with approximation using the above-described calculation method without calculations performed on all the column wirings, it is possible to calculate voltage drop quantities by the matrix operation of Equation 7 and the linear approximation of Equation 9, whereby it is possible to remarkably reduce the number of calculations in comparison with the large scale matrix operation of Equation 6.
In addition, by reducing the number or calculations, it is possible to realize the calculations of Equation 7 and Equation 9 by means of hardware having a very simple construction as described below.
The above description has referred to the calculation of voltage drop quantities according to the invention.
The entire construction of the image display apparatus containing a processing circuit for performing compensation of voltage drops in the above-described manner will be described below.
(Description of the Entire System and the Functions of Individual Parts)
An image display apparatus 100 includes the display panel 1, connecting terminals Dx1 to DxM and Dx1′ to DxM′ of the row wirings of the display panel 1, connecting terminals Dy1 to DyN of the column wirings of the display panel 1, a high-voltage terminal Hv for applying an acceleration voltage between a faceplate 1007 and a rear plate 1005 (refer to
An inverse γ conversion part 9 inversely converting a video signal which is γ-corrected to show linear luminance characteristics when displayed on a CRT, into a signal for the display panel 1 of the invention. A timing generating circuit 4 generates timing for each part. A shift register 5 stores data for one line. A latch circuit 6 is a circuit which latches data for one line. Voltage drop compensation means A according to the first embodiment has an input converting part 10, a voltage drop quantity calculating part 11, a delay circuit part 12, an operation part 13, and an output converting part 14.
Incidentally, the image display apparatus 100 according to the first embodiment is capable of coping with various video sources such as SD, HD and MPEG, but for the sake of simplicity, the following description will refer to processing subsequent to decoding into R, G and B video signals (In the processing of the invention, since different processes are not executed on R, G and B video signals, the following description refers to the processing of a single video signal).
(Scanning Circuit)
The scanning circuits 2 and 2′ output a selecting potential Vs or a non-selecting potential Vns to the connecting terminals Dx1 to DxM and Dx1′ to DxM, respectively, in order to sequentially scan the display panel 1 on a row-by-row basis.
The scanning circuits 2 and 2′ perform scanning by sequentially switching scanning wirings to be selected, at intervals of one horizontal scanning period in synchronism with a timing signal Tscan from the timing generating circuit 4.
Incidentally, the timing signal Tscan is a group of timing signals produced from a vertical scanning signal and a horizontal scanning signal.
Each of the scanning circuits 2 and 2′ includes M number of switches 201, a shift register 202 and the like, as shown in
In order to reduce voltage drops on the row wirings, it is preferable that, as shown in
(Voltage Drop Compensation Means A)
The voltage drop compensation means A is a circuit which calculates the quantity of a voltage drop to occur on a scanning wiring. The voltage drop compensation means A predicts a voltage drop quantity which averagely occurs during one horizontal scanning period, on the assumption that a temporal variation in the quantity of a voltage drop to occur on a scanning wiring is small as described previously.
(Input Converting Part 10 (Effective Voltage Calculating Means))
The input converting part 10 is means for calculating the effective voltage data AVF[I] (I represents a horizontal position, where I=1, 2, . . . , N) from inverse-γ-converted image data Din[I] in a certain horizontal line in order to find an effective voltage value (an effective voltage averaged in the time direction) obtainable when the image data Din[I] is directly inputted to the modulation circuit 8 which is the modulation means.
More specifically, the input converting part 10 performs conversion such as that shown in
(Voltage Drop Quantity Calculating Part 11)
The voltage drop quantity calculating part 11 is means for calculating a voltage drop quantity from the effective voltage data.
As described above in the first embodiment as well, the voltage drop quantity calculating part 11 is constructed to calculate a voltage drop quantity by using a degenerate model reduced in the number of calculations.
As shown in
The device current converting part 30 is a circuit which converts the effective voltage data into device current data.
The device current converting part 30 converts the effective voltage data AVF [I] (I=1, 2, . . . , N, where I represents a horizontal position) into device current data IF[I] (I=1, 2, . . . , N, where I represents a horizontal position) on the basis of the (device current If) vs. (device driving voltage Vf) curve shown in
The device current summing part 31 divides the horizontal direction of the display screen into a plurality of blocks, and calculates the sum IFB[J] (J=1, 2, . . . , 4, where J represents a block number) of the device currents If of the individual blocks.
The matrix calculation part 32 is a circuit which performs the matrix operation described as Equation 7.
The voltage drop quantity calculating part 11 performs the above-described processing to calculate the voltage drop quantities (voltage drop quantity data) ΔVN1 to ΔVN5 at horizontal positions corresponding to the respective nodes.
To find a voltage drop quantity at an arbitrary position, the horizontal interpolation part 33 performs horizontal interpolation on the discrete voltage drop quantities given by Equation 9. In the invention, interpolation is performed by linear approximation and voltage drop quantity data ΔV[I] (I=1, 2, . . . , N) at an arbitrary horizontal position I is calculated.
(Delay Circuit Part 12)
The delay circuit part 12 is an operation circuit which will be described later, and serves as a circuit which delays the effective voltage data AVF [I] to cause the timing of an effective voltage and the timing of a voltage drop quantity to coincide with each other when the effective voltage and the voltage drop quantity are to be added together.
The delay circuit part 12 delays the effective voltage data AVF [I] and converts it to effective voltage data AVFD[I] (I=1, 2, . . . , N, where I represents a horizontal position), and outputs the effective voltage data AVFD[I] to the operation part 13.
(Operation Part 13)
The operation part 13 serves as means for adding the voltage drop quantities ΔV[I] (I=1, 2, . . . ., N) corresponding to individual horizontal positions to the effective voltage data AVFD[I] (I=1, 2, . . . , N) corresponding to image data Data[I] (I=1, 2, . . . , N) at the individual horizontal positions.
Namely, the following operation is performed by considering the horizontal position I;
CVF[I]=AVFD[I]+ΔV[I] (I=1, 2, . . . , N), [Equation 10]
and corrected effective voltage data CVF[I] is calculated.
(Output Converting Part 14)
The output converting part 14 serves as means for calculating, on the basis of the corrected effective voltage data CVF[I], an input value to be given to the modulation means so that the output of the modulation means provides a similar effective voltage.
Specifically, the output converting part 14 performs the inverse conversion of the conversion shown in
(Shift Register 5 and Latch Circuit 6)
The image data Dout[I] (I=1, 2, . . . , N) which is the output from the operation means is converted from its serial data format to parallel image signals ID1 to IDN for individual column wirings through serial/parallel conversion by the shift register 5. Then, the image signals ID1 to IDN are loaded into the latch circuit 6 by a timing signal Tload immediately before one horizontal scanning period is started. The latch circuit 6 supplies parallel image signals D1 to DN to the modulation means.
In the first embodiment, the image signals ID1 to IDN and D1 to DN are 8-bit image signals, respectively. These shift register 5 and latch circuit 6 operate at operating timing based on a timing control signal Tsft and the timing control signal Tload supplied from the timing generating circuit 4.
(Modulation Means (Circuit) 8)
The modulation circuit 8 is constructed to output the modulated pulse shown in
This image display apparatus is capable of restraining the influence of voltage drops on row wirings which has heretofore been a problem, and ameliorating the degradation of a display image caused by the voltage drops, thereby providing an image of very good quality.
According to the voltage drop compensation method of the first embodiment, it is possible to suitably perform compensation of voltage drops.
On the other hand, there is the possibility that the construction of the first embodiment may cause the problem that the corrected image data Dout[I] exceeds the input range of the modulation means 8 to such an extent that preferable correction becomes impossible.
The cause of this problem is that a voltage corresponding to effective voltage data CFV[I] corrected by performing the correction exceeds the maximum voltage that can be outputted from the modulation means 8.
In the following description of the second embodiment, reference will be made to an example in which measures are taken against such a problem (hereinafter called “overflow”).
The second embodiment differs from the first embodiment in that the inverse-γ-converted image data Din[I] is multiplied by a mixed coefficient smaller than 1, thereby reducing a range which can be taken by the image data Din[I] (a multiplier 17).
In the second embodiment, as shown in
It is to be noted that at the time of selection of the coefficient, if 100% full-screen white display is selected as the input, the voltage drop quantity at this time reaches its maximum, and if an overflow does not occur in this case, overflows can be prevented from occurring in any other case.
By constructing the circuit in the above-described manner, it is possible to more suitably perform compensation of voltage drops.
In the second embodiment, it is possible to more suitably perform compensation of voltage drops by multiplying input image data by a fixed gain to take measures against an overflow.
In the following third embodiment, reference will be made to another construction which prevents an overflow.
The third embodiment differs from the second embodiment in that the inverse-γ-converted image data Din[I] is multiplied by a coefficient (gain) which varies on a frame-by-frame basis, thereby reducing a range which can be taken by the image data Din[I].
In the third embodiment, as shown in
G[k]=G[k−1]×MAXin/Dmax[k], [Equation 11]
where G[k] is the gain of the k-th frame.
Furthermore, the input image data Din[I] of the (k+1)-th frame is multiplied by the calculated gain G[k], to limit a range which can be taken by the input image data Din[I] (a multiplier 17).
This method of dynamically varying the gain on a frame-by-frame basis offers the merit of enabling effective use of the output range of the modulation means 8, and is greatly superior in that particular kinds of images can be displayed with higher luminance and higher gray scale levels than can be displayed in the second embodiment.
Incidentally, there is the problem that although the above-described gain calculating method can prevent overflows, a visible flicker may also be caused in an image because the variation of the gain between frames is excessively large.
Referring to
It is also possible to calculate another gain Ga[k] whose variation is restrained by a feedback filter which is shown below by way of example.
Ga[k]=a×G[k]+(1−a)×Ga[k−1], [Equation 12]
where a is a coefficient of 0<a<1.
The image data Din[I] is multiplied by the gain Ga[k] calculated in this manner, whereby overflows can be prevented.
Incidentally, there are some cases where overflows cannot be strictly prevented by filtering the gain.
To completely prevent overflows, a limiter part 19 which completely limits the size of the corrected image data Dout[I] to a range below the input maximum value MAXin of the modulation means 8 is provided as shown in
Namely,
Dout2[I]=Dout[I] (when Dout[I]<MAXin), and
Dout2[I]=MAXin (when Dout[I]≧MAXin). [Equations 13]
When the output Dout[I] limited in this manner is supplied to the input of the shift register 5, greatly preferable modulation can be performed.
The present inventors has confirmed another problem in which when a scene change occurs in an image, a gain before filtering greatly varies, but, on the other hand, the gain is filtered to be restrained in variation, so that a rapid gain change cannot be performed.
Referring to
Further, in the filter part 18 of
Gb[k]=G[k] (in the case where a scene change occurs), and
Gb[k]=a×G[k]+(1−a)×Gb[k−1] (in the case where no scene change occurs),
where a is a coefficient of 0<a<1.
When gain control is performed in this manner, in the same scene, the variation of the gain can be restrained and a flicker-free image can be obtained. Greatly preferably, the gain can be varied rapidly when a scene change occurs.
Incidentally, the detection of a scene change can be easily implemented, for example by a method of calculating the difference between APLs (average picture levels) in each frame and, if the difference is greater than a certain threshold, determines that a scene change has occurred.
By adopting the above-described construction, it is possible to suitably prevent the above-described overflows, and, far more preferably, it is possible to suitably perform compensation of voltage drops.
In the description of the third embodiment, reference has been made to the voltage drop compensation means which adopts measures against overflows occurring during the compensation of voltage drops.
However, the construction shown in
Namely, in the third embodiment, overflows are prevented by using input data which is previously reduced in size, but in the fourth embodiment, input data are not previously reduced in size, and the size of data is reduced immediately before the data is inputted to the modulation means 8.
In the fourth embodiment, as shown in
Gc[k]=MAxin/Dmax[k] [Equation 15]
where Gc[k] is the gain of the k-th frame.
In addition, as to the calculated gain Gc[k], measures to restrain the variation of the gain are taken by means of a filter (low-pass filter) for smoothing the variation of the gain between frames.
For example, another gain Gd[k] whose variation is restrained by a feedback filter which is shown below is calculated (the filter part 18).
Gd[k]=a×Gc[k]+(1−a)×Gd[k−1] [Equation 16]
where a is a coefficient of 0<a<1.
In addition, the scene change detecting part 20 is provided for the purpose of rapidly varying the gain when a scene changes, and supplies to the filter part 18 the signal schg indicative of whether a scene change has occurred.
Further, in the filter part 18 of
Ge[k]=Gc[k] (in the case where a scene change occurs), and
Ge[k]=a×G[k]+(1−a)×Ge[k−1] (in the case where no scene change occurs), [Equations 17]
where a is a coefficient of 0<a<1.
The image data Din[I] is multiplied by the gain Ge[k] calculated in this manner, whereby overflows can be prevented (a multiplier 21).
Furthermore, the corrected image data Dout [I] of the (k+1)-th frame is multiplied by the calculated gain Ge[k], thereby calculating corrected image data Dout3[I] which can take a limited range.
Dout3[I]=Ge[k]×Dout[I]. [Equation 18]
Further, in the fourth embodiment as well, to completely prevent overflows due to filtering, the limiter part 19 which completely limits the size of the corrected image data Dout[I] to a range below the input maximum value MAXin of the modulation means 8 is provided as shown in
Namely,
Dout4[I]=Dout3[I] (when Dout3[I]<MAXin), and
Dout4[I]=MAXin (when Dout3[I]≧MAXin). [Equations 19]
When the output Dout4[I] limited in this manner is supplied to the input of the shift register 5, greatly preferable modulation can be performed.
By adopting the above-described construction, it is possible to suitably prevent the above-described overflows, and, far more preferably, it is possible to suitably perform compensation of voltage drops.
As described hereinabove, according to the invention, it is possible to obtain preferable display images by suitably compensating for the influence of voltage drops by employing modulation which uses both modulation of pulses in the voltage direction and modulation of pulses in the time direction.
Number | Date | Country | Kind |
---|---|---|---|
2002-380617 | Dec 2002 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5555000 | Sarrasin et al. | Sep 1996 | A |
5734361 | Suzuki et al. | Mar 1998 | A |
6515641 | Sagano et al. | Feb 2003 | B1 |
6580407 | Suzuki et al. | Jun 2003 | B1 |
20020089473 | Yamazaki et al. | Jul 2002 | A1 |
20030011545 | Sagano et al. | Jan 2003 | A1 |
20030016195 | Sagano et al. | Jan 2003 | A1 |
Number | Date | Country |
---|---|---|
8-248920 | Sep 1996 | JP |
8-248921 | Sep 1996 | JP |
10-207424 | Aug 1998 | JP |
2001-109421 | Apr 2001 | JP |
2002-229506 | Aug 2002 | JP |
2002-311885 | Oct 2002 | JP |
WO 9733271 | Sep 1997 | WO |
Number | Date | Country | |
---|---|---|---|
20040165004 A1 | Aug 2004 | US |