Current load device and method for driving the same
This invention provides a precise current load device. A cell includes a power supply line, a ground line, first and second voltage supply lines, a signal line, first, third and fourth control lines, first to fourth switches, a p-type TFT, a capacitance element, and a current load element. A source of the p-type TFT is connected to the power supply line, one terminal of the current load element is connected to the ground line, the first switch is connected between the signal line and a drain of the p-type TFT, the second switch is connected between the drain and the gate of the p-type TFT, the third switch is connected between the drain of the p-type TFT and the current load element, and the fourth switch is connected between the voltage supply line and the current load element.
1. Field of the Invention
The present invention relates to a current load driving circuit for driving a current load element and a method for driving the same. In particular, it relates to a current load device comprising current load elements and current load driving circuits arranged in a matrix, and a method for driving the same.
2. Description of the Prior Art
In recent years, a device having cells arranged in a matrix, each of the cells comprising a current load element that operates depending on a current passing therethrough and a current load driving circuit for driving the current load, has been developed.
For example, in many light emitting display devices with an organic EL (electroluminescence) device serving as the current load element, pixels each comprising the organic EL device and a drive-circuit therefor are arranged in a matrix and driven according to the active matrix method.
A typical configuration of the pixel of the light emitting display device according to this method is shown in
An operation of the pixel according to this first conventional example is as follows. When the control line CL is selected, the switch SW is turned on. At this time, a voltage enough to supply a current according to a current-brightness characteristic of the light emitting device LED is applied to the gate of the TFT Q through the signal line SL so as to cause the light emitting device LED to emit light with brightness at an intended gray-scale level. The gate voltage is maintained (retained) by the capacitance element C, even when the control line CL is deselected and the switch SW1 is turned off. This operation enables the light emitting device LED to maintain brightness at an expected gray-scale level.
The first conventional example has a disadvantage. That is, when there is un-unifomity in TFT's current/voltage characteristics, even if a same voltage is applied to gates, the light emitting devices are supplied with various currents. Consequently, the light emitting devices are not supplied with a current enough to provide an expected brightness, and thus, the quality of the display device is reduced. In particular, there is quite large deviation of current/voltage characteristics of poly-silicon TFTs, which are often used in display devices, so that the image quality thereof is significantly reduced.
To solve the problem, there has been implemented a method of supplying a current to a transistor in the pixel circuit through the signal line, converting the current into a voltage by the transistor and maintaining (retaining) the voltage.
An operation of the pixel according to this second conventional example is as follows. When the control line CL is selected, the switches SW1 and SW2 are turned on. At this time, a current according to a current-brightness characteristic of the light emitting device LED flows through the signal line SL to cause the light emitting device LED to emit light with a brightness at an intended gray-scale level. This current flows between the drain and source of the TFT Q2. However, since the gate and drain of the TFT Q2 are short-circuited, the gate voltage thereof is set at a value for passing the same current through the TFT Q2 in a saturation region, and the voltage is retained by the capacitance element C. The TFT Q1 and the TFT Q2 form a current mirror. Thus, if current/voltage characteristics of TFT Q1 are equal to those of the TFT Q2, a current, whose value is equal to that of the current flowing through TFT Q2 and the signal line SL, flows through the TFT Q1 and is supplied to the light emitting device LED. Then, even if the control line CL is deselected, the gate voltage of the TFT Q1 is maintained (retained) by the capacitance element C. Therefore, the TFT Q1 can supply the current to the light emitting device LED, and the light emitting device LED can maintain brightness at an expected gray-scale level.
An operation of the pixel according to this third conventional example is as follows. If the pixel 2 is selected, the control line CL1 (#K1) enters into an “L” state, the control line CL2 (#K) enters into an “H” state, the p-TFT Qp2 and the p-TFT Qp3 are turned on, and the p-TFT Qp4 is turned off. Then, a current according to a current-brightness characteristic of the light emitting device LED flows through the signal line SL (#M) to cause the light emitting device LED to emit light with a brightness at an intended gray-scale level. This current is supplied to the light emitting device LED through the TFT Qp2 and TFT Qp1. At this time, the p-TFT Qp1 has the drain and the gate short-circuited via the drain and source of the p-TFT Qp3 and operates in the saturation state, the gate voltage of the p-TFT Qp1 is set at a value to provide the current, and the voltage is retained by the capacitance element C. When the selection of the control line shifts from the lines #K to the next, the control line CL1 (#K) enters into the “H” state, the control line CL2 (#K) enters into the “L” state, and the supply of the current from the signal line SL to the pixel is stopped. However, the p-TFT Qp4 is turned on, and the current flows through this transistor. In this case, the gate voltage of the p-TFT Qp1, when the current from the signal line SL flows through the p-TFT Qp1, is maintained (retained) by the capacitance element C. Therefore, the p-TFT Qp1 can supply the current to the light emitting device LED, and the light emitting device LED can maintain a brightness at an expected gray-scale level.
According to the first conventional example described above, the brightness depends on the voltage signal. However, there is quite large deviation of current/voltage characteristics of poly-silicon TFTs, and even if the same voltage is applied to the gates of TFTs, the light emitting devices are supplied with various currents, and thus, the brightness thereof varies. Therefore, there is a disadvantage that it is difficult to cause the light emitting device to emit light with an intended brightness, and the quality of the display device is reduced.
According to the second conventional example, a pair of transistors forming the current mirror are each constituted by a TFT. However, unlike with a crystalline silicon transistor, it is possible that the transistors of the pair have current/voltage characteristics which are significantly different from each other even when they are disposed close to each other. Therefore, a difference in current/voltage characteristics appears between the transistor for retaining (converting) the current and the transistor for supplying the current to the light emitting device, and thus, it becomes difficult to reproduce an intended brightness with high precision.
In the case of the third conventional example described above, if the organic EL or the like is used as the light emitting device, the light emitting device has a capacitance of the order of several pF in parallel therewith, and the capacitance constitutes a load on the driving TFT. Thus, when a pixel is to be selected, it takes a long time for the current value of the driving TFT to settle at a value for supplying an expected current to the light emitting device and for the voltages of the parts to settle in a state where the expected current is supplied to the light emitting device. Therefore, if the selection period is shortened to accommodate higher definition, the selection period will expire before the gate voltage of the p-TFT Qp1 settles at a value at which the current flowing through the signal line equals to the current the p-TFT Qp1 supplies to the light emitting device, and thus, the p-TFT Qp1 cannot supply an expected current to the light emitting device. Then, the light emitting device LED emits light with an unexpected brightness, and thus, the image quality is reduced. That is, the third conventional example has a disadvantage in that enhancing the definition reduces the image quality.
BRIEF SUMMARY OF THE INVENTIONThis invention is to solve such problems of the prior art arising in driving a current load element, and in particular, a light emitting device, such as an organic EL device. A first object of this invention is to provide a current load device which can supply current load elements with high precision. A second object thereof is to provide a current load device which can be increased in definition and size without degradation in device characteristics by allowing a voltage between a source and gate of a driving TFT to quickly settle at a value for passing an expected current through the driving TFT.
In order to attain the objects, according to this invention, there is provided a current load device comprising: a driving transistor having a source connected to a power supply line or a ground line GND directly or via a transistor; a first switch connected between a signal line and a drain of the driving transistor; a second switch connected between the drain of the driving transistor or the signal line and a gate of the driving transistor; a capacitance element having one terminal connected to an appropriate voltage line and the other terminal connected to the gate of the driving transistor; and a serially-connected assembly of a current load element and a third switch, the serially-connected assembly being connected between the ground line or any power supply line and the drain of the driving transistor.
Preferably, the third switch is turned on when the first switch is turned off, and is turned off before the first switch is turned on. More preferably, a fourth switch, which operates oppositely to the third switch, is connected to the current load element in parallel.
In addition, in order to attain the objects, according to this invention, there is provided a method for driving a current load device, the current load device being active-matrix driven and comprising a plurality of cells each comprising a current loadelement, a driving transistor for supplying a driving current to the current load element and a retention capacitance element for retaining a voltage to be applied to the driving transistor, wherein a current is not supplied to the current load element at least during a period in which the retention capacitance element conducts the retaining operation.
Preferably, the supply of the current to the current load element is stopped before the retention capacitance element starts the retaining operation. More preferably, when the supply of the current to the current load element is stopped, charges stored in the current load element are forcedly removed.
[Operation]
According to the arrangement of this invention described above, a switch is provided between the driving transistor for retaining and supplying the current and the current load element, and the switch is held in the off state during a period of operation of retaining the current; that operation is to set a gate voltage of the driving TFT to flow an appropriate current between the drain and the source of the driving TFT via the signal line. Therefore, in retaining the current, the effect of the capacitance of the current load element can be eliminated and the current can be retained in a short time.
Besides, in the case of an arrangement in which the switch SW between the driving transistor for retaining and supplying the current and the current load element is turned off an arbitrary time after the start of the supply of the current to the current load element, the performance of the current load element becomes the time-average performance controlled by the ratio of operating and un-operating period of the current load element. In this case, to attain the same performance as in the case of not stopping the operation, the performance of the current load element needs to be increased while it operates and the current supplied to the current load element has to be increased, so that the current supplied to the signal line is also increased. Therefore, a time required for charging the capacitance of the signal line or load can be reduced, and a time required for retaining the current can be reduced.
In addition, if the current load element is a light emitting device, such as an organic EL device, since the display operation involves the state where the light emission is stopped as described above, the display operation is similar to that of CRTs (cathode ray tubes) and an after image is hard to remain, and thus, moving images can be displayed with higher quality.
BRIEF DESCRIPTION OF THE DRAWINGS
Now, embodiments of the present invention will be described in detail with reference to the drawings. In the following, the description will be made with regard to a light emitting device. However, it is illustrative only, and this invention can be applied to any typical current load element.
First Embodiment
In the first operation state, the TFT Q operates in the saturation region because the second terminal and gate thereof are short-circuited by the switch SW2. Besides, since the switch SW3 has been turned off, any current does not flow through the light emitting device LED, and the light emitting device LED does not operate (emit light). The current supplied from the signal line SL flows into the TFT Q, and depending on the current/voltage characteristics of the TFT Q, the gate voltage of the TFT Q is set at a value for passing the current across the drain and source thereof. At this time, the current from the signal line SL is not supplied to the capacitance of the light emitting device LED, and therefore, the gate voltage of the TFT Q is quickly set at the value for passing the current from the signal line SL across the drain and source of the TFT Q.
The subsequent second operation state (current supplying state) is a state where a row other than that including the shown pixel in the display device is selected, in which the switch SW1 is turned off by the control line CL1, the switch SW2 is turned off by the control line CL2 and the switch SW3 is turned on by the control line CL3.
In the second operation state, the gate voltage of the TFT Q is held by the capacitance element C at the value in the first operation state. Thus, the TFT Q can supply the current supplied thereto from the signal line SL in the first operation state to the light emitting device LED through the switch SW3, and the light emitting device LED operates (emits light) to provide a brightness at an intended gray-scale level.
According to this embodiment, the TFT Q in the pixel retains, depending on the current/voltage characteristics thereof, the gate voltage value to flow a current through the TFT Q from the signal line SL, and the TFT Q having retained the gate voltage value supplies the current, whose value is the same of the current from the signal line SL in the retaining state, to the light emitting device LED. Therefore, the current can be retained and supplied with high precision regardless of the current/voltage characteristics of the TFT Q.
For the operation shown in
In the operation example shown in
The subsequent second operation state (current supplying state) is a state where a row other than that including the pixel shown in
In this state, the gate voltage of the TFT Q is identical to that retained by the capacitance element C in the first operation state, and the TFT Q supplies the current supplied thereto from the signal line SL in the first operation state to the light emitting device LED through the switch SW3 to cause the light emitting device LED to emit light with a brightness at an intended gray-scale level.
In the subsequent third operation state (current stop state), the row other than that including the shown pixel has been selected, and the switch SW3 is turned off by the control line CL3 before the row including the shown pixel is selected again. Thus, the supply of the current to the light emitting device LED is stopped, and the light emitting device LED stops the operation thereof (light emission).
In the third operation example, among the first to third operation states, the light emitting device LED emits light in the second operation state, stops light emission for a short while in the first operation state and does not emit light in the third operation state. Therefore, it is possible to cause the light emitting device LED to emit light only for a fraction of one frame period. For example, if the light emitting device is caused to emit light for one third of one frame period, three times the current is to be supplied thereto to provide the same time-average brightness as in the case of light emission for the whole period. If the current value is raised, a time required for charging a wiring capacitance such as signal line can be reduced, and the period of the first operation state required for retaining the current can be shortened. Therefore, this operation example is ready for the increase in wiring capacitance due to higher definition and larger screen. In addition, since the light emitting device does not emit light in the third operation state in this operation example, the display operation is similar to that of CRTs and an afterimage is hard to remain, and thus, moving images can be displayed with high quality.
In driving according to this operation example, the switches SW1 and SW2 operate the same, and thus, the control lines CL1 and CL2 can be integrated.
The third and second operation examples can be combined with each other. That is, the timing chart shown in
According to the first operation example of this embodiment, in the precharge period in the first operation state, the shown pixel 2 is selected, the switches SW1 and SW3 are turned off, and the switch SW2 is turned on to apply a precharge voltage to the capacitance element C and the gate of the TFT Q through the signal line SL. Then, in the current writing period in the first operation state, as in the first embodiment, the switches SW1 and SW2 are turned on and the switch SW3 is turned off to apply to the capacitance element C and the gate of the TFT Q a voltage for passing the current supplied through the signal line SL across the drain and source of the TFT Q, thereby retaining the current.
According to the operation example of the first embodiment, the voltage is applied to the capacitance element C relying on the current, a low current value would be affected by the load of the signal line SL or the like, so that it would take a long time for the voltage applied to the gate of the TFT Q and the capacitance element to be settled. Thus, a long first operation state would be needed. To the contrary, according to this operation example, the precharge period in the first operation state, in which the voltage is precharged in the gate of the TFT Q and the capacitance element C, is short. When the precharged voltage is changed to an appropriate voltage to be applied to the gate of the TFT Q and the capacitance element C during the current writing period, the current writing period can also be reduced. Thus, the first operation state (total of the precharge period and the current writing period) can be reduced.
A second operation state (current supplying state) is a state where a pixel in a row other than the shown row is selected, in which as in the first embodiment, the switches SW1 and SW2 are turned off and the switch SW3 is turned on to supply the retained current from the TFT Q to the light emitting device LED.
The precharging operation in this operation example can be realized by changing the signal applied to the pixel 2 through the signal line SL without changing the timings of the switching operations according to the first embodiment. However, according to the first embodiment, if a voltage is applied to the gate of the TFT Q and the capacitance element C through the signal line SL in the precharge period in the first operation state, the voltage may be different from the voltage applied to the signal line SL because a current path is established. To the contrary, according to the second embodiment, since only the switch SW 2 is in on state in the precharge period in the first operation state, no current path is established during the precharging. Thus, a precise voltage can be advantageously precharged to the gate of the TFT Q and the capacitance element C.
In this operation example, the timing for switching the switch SW1 from the off state to the on state is modified. Modifying the second and third operation examples of the first embodiment in this way can provide the first embodiment with the advantages of the first operation example of the second embodiment in addition to its original advantages. On the other hand, according to the second embodiment, all the operation example of the first embodiment is possible, and the advantages thereof are also provided. Furthermore, as in the first embodiment, the configuration of the pixel 2 can be simplified by appropriately selecting the types of conductivity of the transistors and integrating the control lines for the operations.
Third Embodiment
According to the third embodiment, the TFT Q2, which is biased by the voltage supply line PB5, is provided. Therefore, the TFT Q1 and the TFT Q2 are cascode-connected to each other and can be both made to operate in the saturation region. Thus, the drain bias dependency of the current/voltage characteristic of TFT Q1 in the saturation region can be improved.
According to the third embodiment, the TFT Q2, which is biased by the voltage supply line PB5, is provided. Therefore, the TFT Q1 and the TFT Q2 are cascode-connected to each other and can be both made to operate in the saturation region. Thus, the drain bias dependency of the TFT Q1 in the saturation region can be improved.
The operation of the pixel in the third embodiment is the same as in the first embodiment except for the operation of the TFT Q2, and the advantages of the operation examples in the first embodiment can be provided. Furthermore, in this embodiment, changing the connection of the switches can realize the same operation as in the second embodiment, and the advantages of the operation example thereof can be provided.
Fourth Embodiment
The subsequent second operation state (current supplying state) is a state where a row other than that including the pixel shown in
In this state, the gate voltage of the TFT Q is identical to that retained by the capacitance element C in the first operation state, and the TFT Q supplies the current supplied thereto from the signal line SL in the first operation state to the light emitting device LED to cause the light emitting device LED to emit light with a brightness at an intended gray-scale level.
In the subsequent third operation state (current stop state), the row other than that including the shown pixel has been selected, and the switch SW3 is turned off by the control line CL3 and the switch SW4 is turned on by the control line CL4 before the row including the shown pixel is selected again. Thus, the supply of the current to the light emitting device LED is stopped, and charges stored in the light emitting device LED are rapidly removed, so that the light emitting device LED stops the operation thereof (light emission).
This operation example is essentially the same as the third operation example according to the first embodiment shown in
In the operation example shown in
Furthermore, in the fourth embodiment, an operation similar to the second and third operation examples in the first embodiment are possible.
Not only the first embodiment, but also each the second and third embodiment performs an operation as that of the fourth embodiment by adding the fourth switch and the fourth control line in the fourth embodiment thereto, respectively. In such cases, the light emission time of the light emitting device can be controlled more accurately without loss of the advantages inherent in the embodiments and there respective operations.
As described in detail with regard to the first embodiment, for the operations in the first to fourth embodiments, the configuration of the pixel 2 can be simplified by appropriately selecting the types of conductivity of the transistors and integrating the control lines. Furthermore, for example, the configuration of the pixel can be simplified by connecting a terminal of the capacitance element C on the other side of the retaining node to the voltage supply line PB1 or PB2, so that the voltage supply line PB3 can be removed. Besides, the value of the voltage applied to the voltage supply line PB3 in the first and second operation state can be changed to change the current supplied to the light emitting device. For example, if the voltage applied to the voltage supply line PB3 in the second operation state is shifted from the voltage value in the first operation state to a level that causes the TFT Q to be turned off, the gate voltage of the TFT Q is also shifted by the same amount on a boot effect, and thus, the current can be prevented from flowing. Thus, a black state can be readily inserted for improving the moving images display.
EXAMPLESNow, examples of the present invention will be described in detail with reference to the drawings. In the following, the description will be made with regard to a light emitting device. However, it is illustrative only, and this invention can be applied to any typical current load element.
First Example
An operation according to this example will be described below.
The first operation state (current retaining state or row selection period) in this operation example is a state where the Kth row in the display device is selected, in which the switches SW1 and SW2 are turned on by the control line CL1 (#K), and the switch SW3 is turned off by the control line CL3 (#K). Besides, a current for providing an intended gray-scale is supplied to the signal line SL (#M) based on the current-brightness characteristic of the light emitting device LED. That is, as shown in
In the first operation state, the p-TFT Qp operates in the saturation region because the drain and the gate thereof is short-circuited by the switch SW2. Besides, since the switch SW3 has been turned off, any current does not flow through the light emitting device LED, and the light emitting device LED does not operate (emit light). The current supplied from the signal line SL (#M) flows into the p-TFT Qp, and depending on the current/voltage characteristics of the p-TFT Qp, the gate voltage of the p-TFT Qp is set at a value for passing the current across the drain and source thereof. At this time, the capacitance of the light emitting device LED is independent of the operation of passing the current through the p-TFT Qp, and needs not to be charged or discharged by the current from the signal line SL (#M). Thus, the gate voltage of the p-TFT Qp is quickly set.
The second operation state (current supplying state) in this example is a state where a row other than the Kth row in the display device is selected, in which the switches SW1 and SW2 are turned off by the signal in the control line CL1 (#K), and the switch SW3 is turned on by the signal in the control line CL3 (#K).
In this operation state, the gate voltage of the p-TFT Qp is held by the capacitance element C at the value in the first operation state, and thus, it is the same as the voltage between the gate and source of the p-TFT Qp in the first operation state. Since the p-TFT Qp supplies the current supplied thereto from the signal line SL (#M) in the first operation state to the light emitting device LED through the switch SW3, the light emitting device LED operates (emits light) to provide a brightness at an intended gray-scale level. That is, at this time, as shown in
In this example, the control timing chart is the same as that in the first example shown in
A signal line SL (#M), a power supply line VCC, a ground line GND, a voltage supply line VS1 and a control line CL1 (#K) run through a pixel 2 according to this example, and a p-TFT Qp1, a p-TFT Qp2, an n-TFT Qn1, an n-TFT Qn2, a capacitance element C and a light emitting device LED are arranged in the pixel 2. In this example, the n-TFT Qn1, the n-TFT Qn2 and the p-TFT Qp2 serve as the switches SW1, SW2 and SW3 in the first example, respectively (the p-TFT Qp1 serves as the p-TFT Qp in the first example). The operation according to the timing chart shown in
A signal line SL (#M), a power supply line VCC, a ground line GND, a voltage supply line VS1, a control line CL1 (#K) and a control line CL2 (#K) run through a pixel 2 according to this example, and a p-TFT Qp1, a p-TFT Qp2, an n-TFT Qn1, an n-TFT Qn2, a capacitance element C and a light emitting device LED are arranged in the pixel 2. This example is different from the third example in that the control line CL2 (#K) is additionally provided and the gate of the n-TFT Qn2 is controlled by the control line CL2 (#K). The operation according to the timing chart shown in
A signal line SL (#M), a power supply line VCC, a ground line GND, a power supply line VS1, a control line CL1 (#K), a control line CL2 (#K) and a control line CL2B (#K) run through a pixel 2 according to this example, and a p-TFT Qp1, a p-TFT Qp2, an n-TFT Qn1, an n-TFT Qn2, an n-TFT Qn3, a capacitance element C and a light emitting device LED are arranged in the pixel 2. This example is different from the fourth example (see
A sixth example is equivalent to the third example (see
A seventh example is equivalent to the fourth example (see
An eighth example is equivalent to the fifth example (see
The first operation state (current retaining state or row selection period) in this example is a state where the Kth row in the display device is selected, in which the switches SW1 and SW2 are turned on by the control line CL1 (#K), and the switch SW3 is turned off by the control line CL3 (#K). Besides, a current for providing an intended gray-scale is supplied to the signal line SL (#M) based on the current-brightness characteristic of the light emitting device LED.
The operation in the first operation state is the same as that in the first example described with reference to FIGS. 10 to 13, and therefore, detailed description thereof is omitted.
The second operation state (current supplying state) in this example is a state where a row other than the Kth row in. the display device is selected, in which the switches SW1 and SW2 are turned off by the control line CL1 (#K), and the switch SW3 is turned on by the control line CL3 (#K).
In the second operation state, the gate voltage of the p-TFT Qp is held by the capacitance element C at the value in the first operation state, and thus, the voltage across the gate and source of the p-TFT Qp is the same as that in the first operation state. Since the p-TFT Qp supplies the current supplied thereto from the signal line SL (#M) in the first operation state to the light emitting device LED through the switch SW3, the light emitting device LED operates (emits light) to provide a brightness at an intended gray-scale level.
The third operation state (current stop state) in this example corresponds to apart of the period of the second operation state before entering into the first operation state, in which the switch SW3 is turned off by the control line CL2 (#K) while the switches SW1 and SW2 are held in the off state by the control line CL1 (#K). During the period, since the switch SW3 is in the off state, any current is not supplied to the light emitting device LED, and the light emitting device LED does not operate (emit light).
According to this example, in addition to the advantages of the capability of quickly retaining a current and supplying the retained current to the light emitting device LED with high precision, which are attained by the first to eighth examples, the following advantage can be expected. In this example, among the first to third operation states, the light emitting device LED emits light in the second operation state, stop slight emission for a short while in the first operation state and does not emit light in the third operation state. Therefore, the time-average brightness of the display device is T2/(T1+T2+T3) times the brightness in the second operation state, where T1 denotes a period of the first operation state, T2 denotes a period of the second operation state and T3 denotes a period of the third operation state. Assuming that one frame period, which is the product of the selection time and the number of stages (rows) to be controlled, is denoted by T, and T1=0.005T, T2=0.25T and T3=0.745T, for example, the brightness of the display device is 0.25 times the brightness in the second operation state. Accordingly, the brightness of the light emitting device LED in the second operation state is required to be about four times higher than that in the second operation state of the examples not having third operation state. If the current-brightness characteristic of the light emitting device LED exhibits a proportionality, the four times larger current is needed. According to this example, due to the presence of the third operation state, the current passing through the light emitting device LED can be larger compared with the other examples. Thus, a time required for charging a wiring capacitance such as signal line can be reduced, and the period of the first operation state required for retaining the current can be shortened. Therefore, this example is ready for the increase in wiring capacitance and the reduction of the selection time due to higher definition and larger screen. In addition, since the light emitting device LED does not emit light in the third operation state in this example, the display operation is similar to that of CRTs and an afterimage is hard to remain, and thus, moving images can be displayed with high quality.
Tenth Example
The operation according to the timing chart shown in
The operation according to the timing chart shown in
As in the case of the second example for the first example, or the sixth to eighth examples for third to fifth examples, for each of the ninth to twelfth example, alternative examples in which the polarities of the TFTs are changed can be contemplated. In such cases, as in the case of the sixth to eighth examples for third to fifth examples, if the switch TFTs are used, the polarities of the TFTs are changed and the signals of the control lines are inverted.
Thirteenth Example
An operation according to the thirteenth example will be described below.
The first operation state (current retaining state or row selection period) in this example is a state where the Kth row is selected, and includes two periods. In the first period (precharge period), the switch SW1 is turned off by the control line CL1 (#K), the switch SW2 is turned on by the control line CL2 (#K) and the switch SW3 is turned off by the control line CL3 (#K). During this period, an appropriate voltage is applied to the gate of the p-TFT Qp through the signal line SL (#M). In the second period (current writing period), the switch SW1 is turned on by the control line CL1 (#K), and the switches SW2 and SW3 are not changed from the respective states in the first period. During this period, a current corresponding to a gray-scale level is supplied to the p-TFT Qp through the signal line SL (#K), the gate voltage of the p-TFT Qp is set at a value for passing the current across the drain and source thereof, and the voltage is maintained (retained) in the capacitance element C. The current writing period is equivalent to the first operation state in the first to twelfth examples.
The second operation state (current supplying state) in this example is a state where a row other than the Kth row in the display device is selected, in which the switches SW1 and SW2 are turned off by the signal in the control line CL1 (#K), and the switch SW3 is turned on by the signal in the control line CL3 (#K). In this operation state, as in the second operation state in the first to twelfth examples, the p-TFT Q supplies the current retained during the first operation state to the light emitting device LED.
This example is characterized in that the first operation state includes the precharge period in which a voltage is applied to the gate of the p-TFT Q. Applying an appropriate precharge voltage to the gate of the p-TFT Q during the precharge period can provide a shortened current writing period only enough for correction. Thus, the period of the first operation state (total of the precharge period and the current writing period) can be shortened. While the first operation state including the similar precharge period can be implemented in the first to twelfth examples, a current path exists during the precharge period. To the contrary, in this example, since the switch SW1 stays off during the precharge period, no current path exist, and the voltage can be applied with high precision.
Here, the arrangement according to the thirteenth example is implemented by modifying the connection of the switch SW2 in the arrangement according to the first example. Therefore, the first to twelfth examples can be similarly modified by changing the position of the switch SW2 as in the thirteenth example.
The operation in the fourteenth example is the same as that in the first example. However, in this example, the p-TFT Qp2, which is biased by the voltage supply line VS3, is provided. Therefore, for example, the p-TFT Qp1 and the p-TFT Qp2 can be both made to operate in the saturation region. Thus, the drain voltage dependency of the current/voltage characteristic of p-TFT Qp1 in the saturation region can be improved.
Here, the arrangement according to the fourteenth example is implemented by adding the p-TFT Qp2 to the arrangement according to the first example. Therefore, the first to twelfth examples can be similarly modified by adding the p-TFT to the arrangements thereof as in the fourteenth example.
In the first operation state (current retaining state or row selection period) in this operation example shown in
The second operation state (current supplying state) in this example is a state where a row other than the Kth row in the display device is selected, in which the switches SW1 and SW2 are turned off by the control line CL1 (#K), the switch SW3 is turned on by the control line CL3 (#K), and the switch SW4 is turned off by the control line CL4 (#K). In the second operation state, the gate voltage of the p-TFT Qp is held by the capacitance element C at the value in the first operation state, and thus, the voltage across the gate and source of the p-TFT Qp is the same as that in the first operation state. Since the current supplied thereto from the signal line SL (#M) in the first operation state is supplied to the light emitting device LED through the switch SW3, the light emitting device LED operates (emits light) to provide a brightness at an intended gray-scale level.
The third operation state (current stop state) in this example, in which a row other than the Kth row in the display device is selected, corresponds to a period in which the switch SW3 is turned off by the control line CL3 (#K) and the switch SW4 is turned on by the control line CL4 (#K) while the switches SW1 and SW2 are held in the off state by the control line CL1 (#K). At the start of this operation state, the switch SW3 is turned off and the switch SW4 is turned on, whereby any current is not supplied to the light emitting device LED, and the voltage VS3 is applied to the anode of the light emitting device. When the voltage VS3 is lower than the emitting voltage of the light emitting device LED, the light emitting device LED instantaneously stops the operation (light emission) at the start of the operation state.
As in the other examples, according to this example, a current can be retained quickly and the retained current can be supplied to the light emitting device LED with high precision.
As in the ninth to twelfth examples, according to this example, the current passing through the signal line SL into the light emitting device LED can be increased. Thus, a time required for charging a wiring capacitance such as signal line can be reduced, and the period of the first operation state required for retaining the current can be shortened. Therefore, this example is ready for the increase of the wiring capacitance element C and the reduction of the selection time due to higher definition and larger screen.
In addition, according to this example, the switch SW4 is provided and can be turned on to apply the voltage VS3 to the light emitting device LED at the start of the third operation state, thereby instantaneously stopping the light emission. In the ninth to twelfth examples, even if the current path is interrupted by the switch SW3, a current is supplied to the light emitting device due to the charges stored in the capacitance of the light emitting device itself. Thus, the light emitting device continues to operate (emit light) until the voltage across the capacitance is sufficiently reduced. This light emission causes an error in determining the brightness of the display device based on the brightness in the second operation state and the periods of the respective operation states. On the other hand, according to this example, since the light emission can be stopped instantaneously by the switch SW4, the brightness of the display device can be determined with high precision based on the brightness in the second operation state and the periods of the first, second and third operation states. Also, as in the ninth to twelfth examples, since the light emission halts in the third operation state, the display operation is similar to that of CRTs, and thus, moving images can be displayed with high quality.
Here, the arrangement according to the fifteenth example is implemented by adding the switch SW4, the control line CL4 (#K) and the voltage supply line VS2 to the arrangement according to the first example (
In the fifteenth example, the voltage supply line VS2 is only needed to feed a voltage for stopping the light emission momentarily when entering the third operation state. Therefore, for example, it may be integrated with the ground line GND to simplify the configuration of the pixel 2 in this example.
Sixteenth ExampleIn the first to fifteenth examples, the voltage supply line VS1, which is connected to one terminal of the capacitance element having the other terminal thereof connected to the gate of the TFT, is assumed to be kept at a constant voltage. Therefore, the power supply line VCC or ground line GND may serve also as the voltage supply line VS1, and in such a case, the configuration of the pixel can be simplified. The value of the current to be supplied to the light emitting device can be changed by varying the voltage value of the voltage supply line VS1 in the first operation state from that in the other operation states.
For example, if the voltage of the voltage supply line VS1 is shifted from the value in the first operation state to a level that causes the TFT to be turned off, the TFT can be turned off on the boot effect. If such an operation is performed on the entire light emitting display device or on each line, the entire light emitting display device or each line can be brought into the black state (a state where the light emitting devices are not activated).
The preferred embodiments and examples have been described above. However, this invention is not limited thereto and can be appropriately altered without departing the spirit and scope thereof. For example, as described above, elements other than the light emitting device including an inorganic EL and an organic EL device such as a light emitting diode may be used, and a general current load element may be used. The third switch (SW3), which is inserted in the current path of the light emitting device, may be disposed on the side of the poser supply line (or ground line), rather than on the side of the driving transistor for the light emitting device. Furthermore, while the fourth switch (SW4) is provided only in the case where the third switch is turned off earlier in the examples, it may be provided in the display device in which the third switch is turned off when the first switch is turned on. Furthermore, the switch used in this invention is not limited to the TFT switch. The switch is essentially prescribed with regard to operation thereof. While the examples involving the simplified configuration have been described in the above-described examples, the transistor serving as the switch may have any polarity as far as it adequately operates.
A first advantage of this invention is that a precise current can be supplied to the current load element. A first reason therefor is that the signal is supplied to the signal line via the current, and the same transistor serves both to retain the current flowing through the signal line and to supply the current to the current load element, thereby preventing the performance of the current load element from being affected by the characteristic variation between the transistors. A second reason therefor is that the current from the signal line can be retained accurately because the current is retained in the state where any current is not supplied to the current load element.
A second advantage is that a time required for retaining the current is short, and a higher definition can be supported. This is due to the fact that the switch between the transistor for retaining the current and the current load element stays off during a period of retaining the current, and thus, the retaining of the current can be conducted without being affected by the high load of the current load element (capacitance and resistance in parallel).
Furthermore, according to the example in which the switch SW2 is turned off earlier than the switch SW1, the noise caused when the switch SW1 is changed in its state can be prevented from being transmitted to the gate of the TFT for driving the current load element. Thus, a high precision current can be supplied to the current load element.
Furthermore, according to the example in which the switch SW2 is interposed between the signal line and the gate of the transistor for supplying a current, highly precise precharging operation can be performed, and the period for retaining the current can be shortened.
Furthermore, according to the example in which the transistor is interposed between the transistor for supplying a current and the power supply line, the drain voltage dependency of the drain current of the transistor for supplying a current can be improved by appropriately biasing the gate of the transistor. Thus, a high precision current can be supplied to the current load element.
In the case where the current load element is the light emitting device, according to the example in which an operation state where any current does not flow through the light emitting device is provided during a period in which the pixel is deselected, the current to be retained can be increased, so that the current can be retained in a shorter time, and the operation becomes similar to that of CRTs, so that an afterimage is hard to remain. Thus, moving images can be displayed with higher quality.
Claims
1-22. (canceled)
23. method for driving a current load device, the current load device being active-matrix driven and comprising a plurality of cells each comprising a current load element, the method comprising:
- driving, by a driving transistor, the current load element; and retaining, by a retention capacitance element, a voltage to be applied to said driving transistor, wherein said current load element has not been driven not only for the period in which said retention capacitance element is setting an appropriate voltage level to be retained therein, but also for a part of the period in which said retention capacitance element does not perform the setting operation.
24. The method for driving a current load device according to claim 23, wherein the supply of the current to said current load element is stopped before the operation for setting the voltage level for said retention capacitance element.
25. The method for driving a current load device according to claim 23, wherein when the supply of the current to said current load element is stopped, charges stored in said current load element is forcedly removed.
26. The method for driving a current load device according to claim 23, wherein when setting the voltage level for said retention capacitance element, said driving transistor operates in a saturation region.
27. The method for driving a current load device according to claim 23, wherein when setting the voltage level for said retention capacitance element, the performance of passing the current through said driving transistor is set after the performance of supplying the voltage to said retention capacitance element and said driving transistor.
28. The method for driving a current load device according to claim 23, wherein the operation for setting the voltage level for said retention capacitance element includes a period in which the current flowing through the signal line is passed across a drain and source of said driving transistor.
29. The method for driving a current load device according to claim 23, wherein a performance of said current load element is set based on two factors, a first factor being the performance of said current load element in the case of being driven by said driving transistor, and a second factor being a ratio between a period in which said current load element operates and a period in which said current load element does not operate.
30-31. (canceled)
32. The method for driving a current load device according to claim 23, wherein said current load element is a light emitting device.
33. The method for driving a current load device according to claim 23, wherein said current load element is an organic EL device.
34-35. (canceled)
Type: Application
Filed: Feb 9, 2007
Publication Date: Jun 21, 2007
Inventor: Katsumi Abe (Tokyo)
Application Number: 11/704,874
International Classification: G09G 3/30 (20060101);