Computer graphics processing and selective visual display system – Display driving control circuitry
Reexamination Certificate
2001-06-26
2004-05-04
Hjerpe, Richard (Department: 2674)
Computer graphics processing and selective visual display system
Display driving control circuitry
C327S333000
Reexamination Certificate
active
06731273
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a level shifter used in a driver circuit for a display device, and in particular, to a level shifter used in a driver circuit for a display device, the driver circuit using thin film transistors (hereinafter referred to as TFTs) formed on an insulator. It is to be noted that, in this specification, a display device means one used as an LCD (a liquid crystal display), an OLED (an organic EL display), or the like.
2. Description of the Related Art
Recently, semiconductor microfabrication technology has been advanced, which is accompanied by miniaturization of LSIs. This results in more active application of such LSIs to small-sized apparatus such as personal digital assistants, which requires lower power consumption of such LSIs. Today, LSIs driven at low power supply voltage such as 3.3 V are mainly used.
On the other hand, with regard to LCDs (liquid crystal displays) the demands for which are remarkably increasing these days in the field of personal digital assistants, monitors for computers, and the like, liquid crystal is often driven by a signal having the voltage amplitude of 10 V-20 V. Therefore, a driver circuit of such liquid crystal includes at least a circuit portion driven by high power supply voltage.
Accordingly, it is indispensable that a controller LSI using the abovementioned LSI which is driven at low power supply voltage is connected to a circuit for driving the liquid crystal which is driven at high power supply voltage through a level shifter for changing the amplitude voltage of the signal.
FIGS. 12A and 12B
illustrate circuit diagrams of commonly used level shifters. It is to be noted that in this specification each power supply potential is denoted as VDD# (# is a numeral) or GND. Here, VDD
1
, VDD
2
, VDD
3
, and VDD
4
are used wherein VDD
4
<VDD
3
<GND<VDD
1
<VDD
2
. For the sake of simplicity, GND is fixed to 0 V.
The level shifter illustrated in
FIG. 12A
converts an input signal having the voltage amplitude of GND−VDD
1
into an output signal having the voltage amplitude of GND−VDD
2
. More specifically, the amplitude is converted by fixing the lower potential side and converting the potential at the higher potential side. The level shifter is structured as follows. Both of a source region of a first p-type TFT
1201
and a source region of a second p-type TFT
1202
are connected to the power supply VDD
2
. A drain region of the first p-type TFT
1201
is connected to a source region of a third p-type TFT
1203
, and a drain region of the second p-type TFT
1202
is connected to a source region of a fourth p-type TFT
1204
. A drain region of the third p-type TFT
1203
is connected to a drain region of a first N type thin film transistor (hereinafter referred to as an n-type TFT) and a gate electrode of the second p-type TFT
1202
. A drain region of the fourth p-type TFT
1204
is connected to a drain region of a second n-type TFT
1206
and a gate electrode of the first p-type TFT
1201
. Both of a source region of the first n-type TFT
1205
and a source region of the second n-type TFT
1206
are connected to GND (=0 V). An input signal (In) is input to a gate electrode of the third p-type TFT
1203
and a gate electrode of the first n-type TFT
1205
. An inverted signal of the input signal (Inb) is input to a gate electrode of the fourth p-type TFT
1204
and a gate electrode of the second N-type TFT
1206
. An output signal (Out) is taken out from the drain region of the fourth n-type TFT
1204
. Here, an inverted output signal (Outb) can also be taken out from the drain region of the third p-type TFT
1203
.
It is to be noted that, though there are n-type and p-type as the conductive types of a TFT, in this specification, in the case where the polarity of a TFT is not specifically limited, the conductive types are described as a first conductive type and a second conductive type. For example, when the first conductive type TFT is of the n-type, the second conductive type means the p-type. Conversely, when the first conductive type TFT is of the p-type, the second conductive type means the n-type.
Next, basic operation of the conventional level shifter is described. When an Hi signal is input as the input signal (In), the n-type TFT
1205
is in a conductive state while the p-type TFT
1203
is in a nonconductive state. Therefore, a signal having the potential of GND, that is, an Lo signal, is input to the gate electrode of the p-type TFT
1202
, and the p-type TFT
1202
is in a conductive state. On the other hand, here, the inverted input signal (Inb) is an Lo signal. Therefore, the n-type TFT
1206
is in a nonconductive state while the p-type TFT
1204
is in a conductive state. Since both of the p-type TFTs
1202
and
1204
are in a conductive state, an Hi signal is outputted as the output signal (Out) with the potential of VDD
2
. It is to be noted that the p-type TFT
1201
is in a nonconductive state, which assures that the potential of the gate electrode of the p-type TFT
1202
is held at Lo=GND.
When the potential of the input signal (In) is Lo, since the level shifter illustrated in
FIG. 12A
is structured to be symmetrical, an Lo signal is outputted from the output terminal (Out) with the potential of GND, that is, 0 V.
In this way, an input signal having the voltage amplitude of GND−VDD
1
is converted into an output signal having the voltage amplitude of GND−VDD
2
.
Next, the level shifter illustrated in
FIG. 12B
converts an input signal having the voltage amplitude of VDD
3
−GND into an output signal having the voltage amplitude of VDD
4
−GND. More specifically, the amplitude is converted by fixing the higher potential side and converting the potential at the lower potential side. The level shifter is structured as follows. Both of a source region of a first n-type thin film transistor (hereinafter referred to as an n-type TFT)
1211
and a source region of a second n-type TFT
1212
are connected to a power supply VDD
4
. A drain region of the first n-type TFT
1211
is connected to a source region of a third n-type TFT
1213
, and a drain region of the second n-type TFT
1212
is connected to a source region of a fourth n-type TFT
1214
. A drain region of the third n-type TFT
1213
is connected to a drain region of a first p-type thin film transistor (hereinafter referred to as a p-type TFT)
1215
and a gate electrode of the second n-type TFT
1212
. A drain region of the fourth n-type TFT
1214
is connected to a drain region of a second p-type TFT
1216
and a gate electrode of the first n-type TFT
1211
. Both of a source region of the first p-type TFT
1215
and a source region of the second p-type TFT
1216
are connected to GND (=0 V). An input signal (In) is input to a gate electrode of the third n-type TFT
1213
and a gate electrode of the first p-type TFT
1215
. An inverted signal of the input signal (Inb) is input to a gate electrode of the fourth n-type TFT
1214
and a gate electrode of the second p-type TFT
1216
. An output signal (Out) is taken out from the drain region of the fourth n-type TFT
1214
. Here, an inverted output signal (Outb) can also be taken out from the drain region of the third n-type TFT
1213
.
Next, basic operation of the conventional level shifter is described. When an Lo signal is input as the input signal (In), the p-type TFT
1215
is in a conductive state while the n-type TFT
1213
is in a nonconductive state. Therefore, a signal having the potential of GND, that is, an Hi signal, is input to the gate electrode of the n-type TFT
1212
, and the n-type TFT
1212
is in a conductive state. On the other hand, here, the inverted input signal (Inb) is an Hi signal at this time. Therefore, the p-type TFT
1216
is in a nonconductive state while the n-type TFT
1214
is in a conductive state. Since both of the n-type TFTs
1212
and
1214
are in a conductive state, an Lo signal is outputted as the output signal (Ou
Atsumi Tomoaki
Azami Munehiro
Koyama Jun
Shionoiri Yutaka
Cook Alex McFarron Manzo Cummings & Mehler, Ltd.
Hjerpe Richard
Laneau Ronald
Semiconductor Energy Laboratory Co,. Ltd.
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