Semiconductor CMOS gate array

A semiconductor device of a master slice type comprises a basic cell comprising: first and second MOS transistors of a first conductivity type in each of which one of a source region and a drain region is commonly used; third and fourth MOS transistors of the first conductivity type in each of which one of a source region and a drain region is commonly used; fifth and sixth MOS transistors of a second conductivity type in each of which one of a source region and a drain region is commonly used; and seventh and eighth MOS transistors of the second conductivity type in each of which one of a source region and a drain region is commonly used. Gate electrodes of the first and third MOS transistors are commonly used, gate electrodes of the second and fourth MOS transistors are commonly used, and gate electrodes of the fifth and seventh MOS transistors are commonly used.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a semiconductor device of a master slice 
type. 
2. Description of the Prior Art 
A gate array is known as a semiconductor device of the master slice type. A 
CMOS gate array is known as one kind of such gate arrays. FIG. 1 shows an 
example of a basic cell of a conventional CMOS gate array. As shown in 
FIG. 1, a basic cell of the conventional CMOS gate array comprises two 
p-channel MOS transistors T.sub.1 and T.sub.2 and two n-channel MOS 
transistors T.sub.3 and T.sub.4. Values of W/L (W: channel width, L: 
channel length) of the p-channel MOS transistors T.sub.1 and T.sub.2 are 
equal. Values of W/L of the n-channel MOS transistors T.sub.3 and T.sub.4 
are also the same. Reference numerals 101 to 104 denote gate electrodes. 
Reference numerals 105 to 107 indicate p.sup.+ -type semiconductor regions 
which are used as source regions or drain regions of the p-channel MOS 
transistors T.sub.1 and T.sub.2. The semiconductor regions 105 to 107 are 
formed in, for example, an n-well formed in a semiconductor substrate (not 
shown). On the other hand, reference numerals 108 to 110 indicate, for 
instance, n.sup.+ -type semiconductor regions which are used as source 
regions or drain regions of the n-channel MOS transistors T.sub.3 and 
T.sub.4. The semiconductor regions 108 to 110 are formed in, for example, 
a p-well formed in the semiconductor substrate (not shown). In this case, 
the p-channel MOS transistor T.sub.1 is formed by the gate electrode 101 
and the semiconductor regions 105 and 106. The p-channel MOS transistor 
T.sub.2 is formed by the gate electrode 102 and the semiconductor regions 
106 and 107. Similarly, the n-channel MOS transistor T.sub.3 is formed by 
the gate electrode 103 and the semiconductor regions 108 and 109. The 
n-channel MOS transistor T.sub.4 is formed by the gate electrode 104 and 
the semiconductor regions 109 and 110. Reference numeral 111 denotes, for 
instance, an n.sup.+ -type semiconductor region which is used to make a 
wiring to supply a power source voltage V.sub.DD contact the n-well. 
Reference numeral 112 indicates, for instance, a p.sup.+ -type 
semiconductor region which is used to make a wiring to supply a power 
source voltage V.sub.SS contact the p-well. 
There are the following problems in the case of constructing, for instance, 
a full CMOS type static RAM by the conventional CMOS gate array comprising 
the basic cell shown in FIG. 1 mentioned above. That is, memory cells of 
the full CMOS type static RAM are ordinarily constructed by four n-channel 
MOS transistors and two p-channel MOS transistors. Therefore, in the case 
of constructing the memory cells of the full CMOS type static RAM by using 
the basic cells shown in FIG. 1, two such basic cells are needed. In this 
case, two p-channel MOS transistors remain. That is, in the case of 
constructing the memory cells of the full CMOS type static RAM by using 
the basic cells shown in FIG. 1, the half of one basic cell is not used 
and the use efficiency of the basic cell is low. Thus, it is difficult to 
improve the integration density of the memory cells. 
On the other hand, in the case of constructing a 2-input NAND circuit, a 
2-input NOR circuit, an inverter circuit, a transmission circuit, or the 
like by using the basic cell shown in FIG. 1, the optimum circuit 
construction cannot be easily obtained due to reasons such that a degree 
of freedom of wirings among the transistors is small and the like. 
OBJECTS AND SUMMARY OF THE INVENTION 
It is, therefore, an object of the invention to provide a semiconductor 
device of the master slice type in which in the case of constructing a 
full CMOS type static RAM, a high integration density of memory cells can 
be realized. 
Another object of the invention is to provide a semiconductor device of the 
master slice type in which in the case of constructing a NAND circuit, a 
NOR circuit, or the like, a circuit construction near the optimum 
construction can be realized. 
According to an aspect of the invention, there is provided a semiconductor 
device of a master slice type, comprising a basic cell comprising: first 
and second MOS transistors of a first conductivity type in each of which 
one of a source region and a drain region is commonly used; third and 
fourth MOS transistors of the first conductivity type in each of which one 
of a source region and a drain region is commonly used; fifth and sixth 
MOS transistors of a second conductivity type in each of which one of a 
source region and a drain region is commonly used; and seventh and eighth 
MOS transistors of the second conductivity type in each of which one of a 
source region and a drain region is commonly used, gate electrodes of the 
first and third MOS transistors being commonly used, gate electrodes of 
the second and fourth MOS transistors being commonly used, and gate 
electrodes of the fifth and seventh MOS transistors being commonly used. 
According to the invention, the basic cell is constructed by four MOS 
transistors of the first conductivity type and four MOS transistors of the 
second conductivity type. Therefore, a memory cell of a full CMOS type 
static RAM comprising two p-channel MOS transistors and four n-channel MOS 
transistors can be constructed by such a basic cell. In this case, 
although two p-channel MOS transistors in the basic cell remain, those two 
p-channel MOS transistors merely occupy about 1/4 of the basic cell. 
Therefore, the use efficiency of the basic cell is higher as compared with 
the case of constructing the memory cell of the full CMOS type static RAM 
by using the conventional basic cell shown in FIG. 1. Thus, the high 
integration density of the memory cell can be realized. Further, as 
compared with the conventional basic cell shown in FIG. 1, the degree of 
freedom of the wirings among the transistors is larger. Therefore, in the 
case of constructing a NAND circuit, a NOR circuit, or the like, a circuit 
construction near the optimum construction can be realized. 
The above, and other, objects, features and advantages of the present 
invention will become readily apparent from the following detailed 
description thereof which is to be read in connection with the drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Embodiments of the present invention will be described hereinbelow with 
reference to the drawings. All of the following embodiments are 
embodiments in the case of using a CMOS gate array of the sea of gates 
type. In all of the drawings of the embodiments, the same Portions are 
designated by the same reference numerals. 
FIG. 2 shows an embodiment of the invention. This embodiment is an 
embodiment in which a full CMOS type static RAM is constructed by a CMOS 
gate array of the sea of gates type. FIG. 3 shows an equivalent circuit of 
a memory cell of the full CMOS type static RAM shown in FIG. 2. FIG. 4 
shows a basic cell of the sea of gates type CMOS gate array which is used 
in the embodiment. 
First, a construction of the basic cell of the sea of gates type CMOS gate 
array which is used in the embodiment will be described. As shown in FIG. 
4, the basic cell which is used in the embodiment comprises four p-channel 
MOS transistors Q.sub.1 to Q.sub.4 and four n-channel MOS transistors 
Q.sub.5 to Q.sub.8. Values of W/L (W: channel width, L: channel length) of 
the p-channel MOS transistors Q.sub.1 to Q.sub.4 are equal. Values of W/L 
of the n-channel MOS transistors Q.sub.5 to Q.sub.6 are also equal. 
Reference characters G.sub.1 to G.sub.5 denote gate electrodes. In this 
case, the gate electrode G.sub.1 is commonly used between the p-channel 
MOS transistors Q.sub.1 and Q.sub.3. The gate electrode G.sub.2 is 
commonly used between the p-channel MOS transistors Q.sub.2 and Q.sub.4. 
The gate electrode G.sub.3 is commonly used between the n-channel MOS 
transistors Q.sub.5 and Q.sub.7. On the other hand, the gate electrodes 
G.sub.4 and G.sub.5 for the n-channel MOS transistors Q.sub.6 and Q.sub.8 
are separated from each other. Each of the gate electrodes G.sub.1 to 
G.sub.5 can be formed by, for instance, an n.sup.+ -type polycrystalline 
silicon (Si) film in which an impurity such as phosphorus (P) was doped or 
a polycide film in which a refractory metal silicide film such as a 
tungsten silicide (WSi.sub.2) film was laid on the n.sup.+ -type 
polycrystalline Si film. 
Reference numerals 1 to 6 denote, for instance, p.sup.+ -type semiconductor 
regions which are used as source regions or drain regions of the p-channel 
MOS transistors Q.sub.1 to Q.sub.4. The semiconductor regions 1 to 6 are 
formed in, for example, an n-well formed in a semiconductor substrate (not 
shown). Reference numerals 7 to 12 denote, for instance, n.sup.+ -type 
semiconductor regions which are used as source regions or drain regions of 
the n-channel MOS transistors Q.sub.5 to Q.sub.8. The semiconductor 
regions 7 to 12 are formed in, for example, a p-well formed in the 
semiconductor substrate (not shown). Reference numeral 13 denotes, for 
instance, an n.sup.+ -type semiconductor region which is used to make a 
connection to connect the power source voltage V.sub.DD within the n-well. 
Reference numeral 14 indicates, for instance, a p.sup.+ -type 
semiconductor region which is used to make a connection to connect the 
power source voltage V.sub.SS with the p-well. 
In the embodiment, the p-channel MOS transistor Q.sub.1 is formed by the 
gate electrode G.sub.1 and the semiconductor regions 1 and 2. The 
p-channel MOS transistor Q.sub.2 is formed by the gate electrode G.sub.2 
and the semiconductor regions 2 and 3. The semiconductor region 2 is 
commonly used between the p-channel MOS transistors Q.sub.1 and Q.sub.2. 
On the other hand, the p-channel MOS transistor Q.sub.3 is formed by the 
gate electrode G.sub.1 and the semiconductor regions 4 and 5. The 
p-channel MOS transistor Q.sub.4 is formed by the gate electrode G.sub.2 
and the semiconductor regions 5 and 6. The semiconductor region 5 is 
commonly used between the p-channel MOS transistors Q.sub.3 and Q.sub.4. 
On the other hand, the n-channel MOS transistor Q.sub.5 is formed by the 
gate electrode G.sub.3 and the semiconductor regions 7 and 8. The 
n-channel MOS transistor Q.sub.6 is formed by the gate electrode G.sub.4 
and the semiconductor regions 8 and 9. The semiconductor region 8 is 
commonly used between the n-channel MOS transistors Q.sub.5 and Q.sub.6. 
The n-channel MOS transistor Q.sub.7 is formed by the gate electrode 
G.sub.3 and the semiconductor regions 10 and 11. The n-channel MOS 
transistor Q.sub.8 is formed by the gate electrode G.sub.5 and the 
semiconductor regions 11 and 12. The semiconductor region 11 is commonly 
used between the p-channel MOS transistors Q.sub.7 and Q.sub.8. 
An example of the dimensions of the basic cell shown in FIG. 4 is as 
follows. For instance, when a design rule is set to 0.7 .mu.m, assuming 
that a length of one unit on design is set to 1G (grid), dimensions A and 
B (FIG. 4) of the basic cell can be set to 14G and 3.5G, respectively. For 
instance, assuming that 1G= 2.1 .mu.m, A=14.times.2.1=29.4 .mu.m and 
B=3.5.times.2.1=7.35 .mu.m. On the other hand, W/L of the p-channel MOS 
transistors Q.sub.1 to Q.sub.4 are such that W/L=4.9 .mu.m/0.8 .mu.m. W/L 
of the n-channel MOS transistors Q.sub.5 to Q.sub.8 are such that W/L=4.2 
.mu.m/0.7 .mu.m. The values of W/L of the p-channel MOS transistors 
Q.sub.1 to Q.sub.4 and the n-channel MOS transistors Q.sub.5 to Q.sub.8 
are almost equal. In this case, a performance ratio of the p-channel MOS 
transistors Q.sub.1 to Q.sub.4 to the n-channel MOS transistors Q.sub.5 to 
Q.sub.8 is proportional to a ratio of the hole mobility to the electron 
mobility. 
Explanation will now be made with respect to an embodiment in which a full 
CMOS type static RAM is constructed by the sea of gate type CMOS gate 
array comprising the basic cell shown in FIG. 4. 
As shown in FIGS. 2 and 3, in the embodiment, a flip-flop circuit of the 
memory cell of the full CMOS type static RAM is constructed by the 
p-channel MOS transistors Q.sub.1 and Q.sub.4 and the n-channel MOS 
transistors Q.sub.8 ' and Q.sub.6. Here, the n-channel MOS transistor 
Q.sub.8 ' corresponds to the n-channel MOS transistor Q.sub.8 among the 
MOS transistors constructing the basic cell adjacent to the basic cell 
comprising the p-channel MOS transistors Q.sub.1 to Q.sub.4 and the 
n-channel MOS transistors Q.sub.5 to Q.sub.8. One of CMOS inverters 
constructing the flip-flop circuit is constructed by the p-channel MOS 
transistor Q.sub.1 and the n-channel MOS transistor Q.sub.8 '. The other 
CMOS inverter is constructed by the p-channel MOS transistor Q.sub.4 and 
the n-channel MOS transistor Q.sub.6. In this case, the p-channel MOS 
transistors Q.sub.1 and Q.sub.4 are used as load transistors. The 
n-channel MOS transistors Q.sub.8 ' and Q.sub.6 are used as driver 
transistors. On the other hand, the n-channel MOS transistors Q.sub.7 ' 
and Q.sub.5 are used as access transistors. The n-channel MOS transistor 
Q.sub.7 ' corresponds to the n-channel MOS transistor Q.sub.7 among the 
MOS transistors constructing the basic cell adjacent to the basic cell 
comprising the p-channel MOS transistors Q.sub.1 to Q.sub.4 and the 
n-channel MOS transistors Q.sub.5 to Q.sub.8. On the other hand, W denotes 
a word line and B.sub.1 and B.sub.2 indicate bit lines. 
In the embodiment, the wiring is executed by using aluminum (Al) wirings of 
three layers. In FIG. 2, X denotes a contact portion of the A1 wiring of 
the first layer and the p.sup.+ -type or n.sup.+ -type semiconductor 
region or gate electrode, .largecircle. indicates a contact portion of the 
A1 wiring of the second layer and the A1 wiring of the first layer, and 
.quadrature. represents a contact portion of the A1 wiring of the third 
layer and the A1 wiring of the second layer. In FIG. 2, the A1 wirings of 
the first, second, and third layers passing through the contact portions 
are shown by a solid line (--), a broken line (-- -- --) and an alternate 
long and short dash line ( ) respectively. In this case, the wirings to 
supply the power source voltage V.sub.DD and V.sub.SS are constructed by 
the A1 wiring of the first layer. The A1 wiring of the first layer to 
supply the power source voltage V.sub.DD is come into contact with the 
semiconductor regions 2, 5, and 13. On the other hand, the A1 wiring of 
the first layer to supply the power source voltage V.sub.SS is come into 
contact with the semiconductor regions 9, 12, and 14. Further, the A1 
wiring of the first layer to supply the power source voltage V.sub.SS for 
the basic cell adjacent to the basic cell comprising the p-channel MOS 
transistors Q.sub.1 to Q.sub.4 and the n-channel MOS transistors Q.sub.5 
to Q.sub.8 is come into contact with semiconductor regions 12' and 14'. On 
the other hand, a word line W is constructed by the A1 wiring of the 
second layer. The bit lines B.sub.1 and B.sub.2 are constructed by the A1 
wirings of the third layer. The bit line B.sub.1 constructed by the A1 
wiring of the third layer is come into contact with a semiconductor region 
10' through the A1 wiring of the second layer and the A1 wiring of the 
first layer. Similarly, the bit line B.sub.2 constructed by the A1 wiring 
of the third layer comes into contact with the semiconductor region 7 
through the A1 wiring of the second layer and the A1 wiring of the first 
layer. 
As mentioned above, according to the embodiment, the full CMOS type static 
RAM is constructed by the CMOS gate array comprising the basic cell shown 
in FIG. 4. Therefore, the memory cell of the full CMOS type static RAM can 
be substantially constructed by one basic cell shown in FIG. 4, though the 
memory cell extends over the two adjacent basic cells. In this case, 
although two p-channel MOS transistors in the basic cell are not used but 
remain, those unused p-channel MOS transistors merely occupy about 1/4 of 
the basic cell. Therefore, the use efficiency of the basic cell is higher 
than the case of constructing the memory cell of the full CMOS type static 
RAM by using the basic cell shown in FIG. 1. Thus, the full CMOS type 
static RAM in which the integration density of the memory cells is higher 
as compared with the conventional one can be easily realized by the CMOS 
gate array. 
In the embodiment, the wiring has been performed by using the A1 wirings of 
three layers as mentioned above. However, for instance, if each channel 
width of the p-channel MOS transistors Q.sub.1 to Q.sub.4 and the 
n-channel MOS transistors Q.sub.5 to Q.sub.8 is increased by 1G, the bit 
lines B.sub.1 and B.sub.2 can be formed by the A1 wiring of the first 
layer. Therefore, the A1 wiring of the third layer is unnecessary. In this 
case, the wiring can be executed by the A1 wirings of two layers. 
An embodiment in which the invention was applied to a 2-input NAND circuit 
will now be described. 
FIG. 5 shows an embodiment in which a 2-input NAND circuit is constructed 
by the sea of gates type CMOS gate array comprising the basic cell shown 
in FIG. 4. FIG. 6 shows an equivalent circuit of the 2-input NAND circuit 
shown in FIG. 5. 
As shown in FIGS. 5 and 6, in the embodiment, the 2-input NAND circuit is 
constructed by the two p-channel MOS transistors Q.sub.3 and Q.sub.4 and 
the four n-channel MOS transistors Q.sub.5 to Q.sub.8 in the basic cell 
shown FIG. 4. The n-channel MOS transistors Q.sub.5 and Q.sub.7 are 
connected in parallel and the n-channel MOS transistors Q.sub.6 and 
Q.sub.8 are also similarly connected in parallel. In FIG. 6, Q.sub.57 
indicates the n-channel MOS transistors Q.sub.5 and Q.sub.7 which are 
connected in parallel and Q.sub.63 indicates the n-channel MOS transistors 
Q.sub.6 and Q.sub.8 which are connected in parallel. In the embodiment, 
the transistors other than the p-channel MOS transistors Q.sub.3 and 
Q.sub.4 and the n-channel MOS transistors Q.sub.5 and Q.sub.8 mentioned 
above, that is, the p-channel MOS transistors Q.sub.1 and Q.sub.2 are not 
used. 
In FIGS. 5 and 6, V.sub.1 and V.sub.2 denote input voltages to gates of the 
n-channel MOS transistors Q.sub.57 and Q.sub.57 and V.sub.OUT indicates an 
output voltage. 
In the embodiment, the wiring is performed by the A1 wirings of two layers. 
The wirings for V.sub.1, V.sub.2 and V.sub.OUT are constructed by the A1 
wiring of the first layer in a manner similar to the wirings to supply the 
power source voltages V.sub.DD and V.sub.SS. In this case, the A1 wirings 
of the first layer for V.sub.1 and V.sub.2 are come into contact with the 
gate electrodes G.sub.1 and G.sub.5, respectively. On the other hand, the 
A1 wiring of the first layer for V.sub.OUT comes into contact with the 
semiconductor region 5 and is also come into contact with the 
semiconductor region 7 through the A1 wirings of the first and second 
layers. 
According to the embodiment, since the 2-input NAND circuit has been 
constructed by the basic cell shown in FIG. 4, a degree of freedom of the 
wirings among the transistors is larger than that in the case of 
constructing the 2-input NAND circuit by using the conventional basic cell 
as shown in FIG. 7. Therefore, in the case of considering on the 
assumption that the integration densities are the same, the 2-input NAND 
circuit of the circuit construction which is closer to the optimum 
construction as compared with the conventional one can be easily realized. 
Further, since each of the n-channel MOS transistors Q.sub.57 and Q.sub.68 
has a channel width which is twice as large as each channel width of the 
n-channel MOS transistors Q.sub.57 to Q.sub.8, its current driving 
capability is very large. Therefore, the 2-input NAND circuit of a high 
performance can be realized. 
An embodiment in which the invention was applied to a 2-input NOR circuit 
will now be described. 
FIG. 7 shows an embodiment in which a 2-input NOR circuit is constructed by 
the sea of gate type CMOS gate array comprising the basic cell shown in 
FIG. 4. FIG. 8 shows an equivalent circuit of the 2-input NOR circuit 
shown in FIG. 7. 
As shown in FIGS. 7 and 8, in the embodiment, the 2-input NOR circuit is 
constructed by the four p-channel MOS transistors Q.sub.1 to Q.sub.4 and 
the two n-channel MOS transistors Q.sub.5 and Q.sub.6 in the basic cell 
shown in FIG. 4. The p-channel MOS transistors Q.sub.1 and Q.sub.3 are 
connected in parallel and the p-channel MOS transistors Q.sub.2 and 
Q.sub.4 are also similarly connected in parallel. In FIG. 8, Q.sub.13 
denotes the p-channel MOS transistors Q.sub.1 and Q.sub.3 which are 
connected in parallel and Q.sub.24 indicates the n-channel MOS transistors 
Q.sub.2 and Q.sub.4 which are connected in parallel. In the embodiment, 
the transistors other than the p-channel MOS transistors Q.sub.1 to 
Q.sub.4 and the n-channel MOS transistors Q.sub.5 and Q.sub.6, that is the 
n-channel MOS transistors Q.sub.7 and Q.sub.8 are not used. 
In the embodiment, the wiring is performed by the A1 wirings of two layers. 
The wirings for V.sub.1, V.sub.2 and V.sub.OUT are constructed by the A1 
wiring of the first layer in a manner similar to the wirings to supply the 
power source voltages V.sub.DD and V.sub.SS. In this case, the A1 wirings 
of the first layer for V.sub.1 and V.sub.2 are come into contact with the 
gate electrodes G.sub.3 and G.sub.2, respectively. On the other hand, the 
A1 wiring of the first layer for V.sub.OUT is come into contact with the 
semiconductor regions 8 and 6 and is also come into contact with the 
semiconductor region 3 through the A1 wirings of the second and first 
layers. 
According to the embodiment, since the 2-input NOR circuit is constructed 
by the basic cell shown in FIG. 4, a degree of freedom of the wirings 
among the transistors is larger than that in the case of constructing the 
2-input NOR circuit by using the conventional basic cell as shown in FIG. 
1. Therefore, the 2-input NOR circuit of the circuit construction which is 
closer to the optimum construction as compared with the conventional one 
can be easily realized. Further, each of the p-channel MOS transistors 
Q.sub.13 and Q.sub.24 has a channel width which is twice as large as the 
channel width of each of the p-channel MOS transistors Q.sub.1 to Q.sub.4. 
Thus, its current driving capability is almost equal to that of the 
n-channel MOS transistors Q.sub.4 to Q.sub.8. 
Therefore, the 2-input NOR circuit of a high performance can be realized. 
Although the embodiments of the invention have practically been described 
above, the invention is not limited to the above embodiments but various 
modifications based on the technical idea of the invention are possible. 
For instance, the dimensions A and B of the basic cell shown in FIG. 4 and 
the channel width W and channel length L of each of the p-channel MOS 
transistors Q.sub.1 to Q.sub.4 and n-channel MOS transistors Q.sub.5 to 
Q.sub.8 constructing the basic cell can be selected in accordance with the 
necessity. On the other hand, the gate electrodes G.sub.1 to G.sub.5 can 
be also set into shapes different from those in the embodiments. Further, 
a method of wiring among the p-channel MOS transistors Q.sub.1 to Q.sub.4 
and n-channel MOS transistors Q.sub.5 to Q.sub.8 is not limited to the 
above embodiments. 
On the other hand, the invention can be also applied to the case of 
constructing an inverter circuit, a transmission circuit, or the like. 
According to the invention, in the case of constructing, for instance, a 
full CMOS type static RAM, a high integration density of the memory cells 
can be realized. In the case of constructing a NAND circuit, a NOR 
circuit, or the like, the circuit construction near the optimum 
construction can be realized.