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nMOS IC Design Report
Author: 1302509 Zhao Ruimin
Module: EEE 112
Lecturer: Dr.Zhao Ce Zhou
Date: June/5/2015
Abstract
This lab intended to train the experimental skills of the layout designing of the nMOS-
based logic circuit and the understanding of the IC fabrication process. This report pro-
vided a brief summary of the fabrication techniques and process of IC chips, the detailed
calculation process of the parameters required for designing the circuit such as aspect
ratios of transistors, the resistance of resistor, and the the graph of the layout and masks
that were drawn based on provided design rule.
The IC fabrication process basically includes three steps which are Thin Film Forma-
tion, Photolithography and Doping. The design of the IC resistor and the nMOS were all
based on these principles.
The relationship between the VOUT of NOR gate and the aspect ratio of its transistor
is that the ratio increase with the increase of the voltage. The aspect ratios of three
nMOS placed in lower place in circuit were set to be 12 while the load transistor ratio was
calculated to be 0.5. The set VOUT of the NOR gate was 0.1V which is less enough than
the threshold voltage which was 0.3V, fits perfectly with the worst case where ratio is 12
and is not too small to increase the cost largely. The layout of the design drawn in grided
coordinate paper is approximately 52λ× 25λ.
i
Contents
Abstract i
Contents ii
1 Introduction 1
1.1 Background and Objective . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.2 Apparatus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.3 Design Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1.3.1 Design Rule List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1.3.2 Parameter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
2 Methodology 3
2.1 Theory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2.1.1 Fabrication Process of IC chips . . . . . . . . . . . . . . . . . . . . . 3
2.2 Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
2.2.1 Logic Date Truth Table . . . . . . . . . . . . . . . . . . . . . . . . . 6
2.2.2 Parameter Calculation . . . . . . . . . . . . . . . . . . . . . . . . . . 6
2.2.3 Mask Drawing with Design Rule . . . . . . . . . . . . . . . . . . . . 8
3 Discussion 9
3.1 Outcome Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.2 Worst Case Anslysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4 Conclusion 11
4.1 Achievement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
4.2 Limitation and Suggestion . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
A Graph 12
A.1 Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
A.2 Masks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
ii
Section 1
Introduction
1.1 Background and Objective
IC fabrication technique is an essential section for electronic engineering students to
master. After gaining the skill of designing nMOS-based logic gates circuit layout, it will
be possible for us to design much more complicated circuit in the future when working on
designing IC chips. In this particular lab, the layout of a simple logic circuit composed
of a NOR gate and an inverter is required to be designed and minimised. The masks for
each layer that is required for the manufacture of this circuit are expected to be drawn on
a piece of grided paper. The target circuit is presented in Figure below:
(a) (b)
1.2 Apparatus
Table 1.1: Apparatus
Apparatus Functionality
Coordinate Paper Grided paper used to draw the layout onDesign Rule List To be referred to when drawing the layout
1
1.3 Design Specification
1.3.1 Design Rule List [1]
Active Area RulesR1 Minimum Active are Width 3λR2 Minimum Active are Spacing 3λPoly-Silicon RulesR3 Minimum Poly Width 2λR4 Minimum Poly Spacing 2λR5 Minimum Gate extension of Poly over Active 2λR6 Minimum Poly-Active Edge Spacing 1λR7 Minimum Poly-Active Edge Spacing 3λMetal RulesR8 Minimum Metal Width 3λR9 Minimum Metal Spacing 3λContact RulesR10 Poly Contact size 2λR11 Minimum Poly Contact Spacing 2λR12 Minimum Poly Contact to Poly Edge Spacing 1λR13 Minimum Poly Contact to Metal Edge Spacing 1λR14 Minimum Poly Contact to Active Edge Spacing 3λR15 Active Contact size 2λR16 Minimum Active Contact Spacing 2λR17 Minimum Active Contact to Active Edge Spacing 1λR18 Minimum Active Contact to Metal Edge Spacing 1λR19 Minimum Active Contact to Poly Edge Spacing 2λR20 Minimum Active Contact Spacing 6λSupply Rail RulesR21 VDD > 3λR22 Ground > 3λResistor RulesR23 Minimum resistor width 2λ
1.3.2 Parameter
• Load Resistor: RL = 5kΩ
• Aspect Ratio: WL = 12(A/B/C); W
L = 0.5(L)
• Normalized Device Constant: β0 = 1.8× 10−4AV −2
2
Section 2
Methodology
2.1 Theory [2]
2.1.1 Fabrication Process of IC chips
A nMOS-based device mainly consists of four layers in terms of layout design including:
Active layer Mask, Poly-Silicon layer Mask, Contact layer Mask and Metal Mask. To
actually fabricate it, there are primarily three steps which are Thin Film Formation,
Photolithography and Doping.
Thin Film Formation
First, the wafers serve as the bottom materials, and then thin and uniform deposited
films ranging from metals to semiconductors and even to insulators are placed onto the
wafers. There concrete commonly utilized placing process are oxidation, chemical vapour
deposition (CVD) forming and physical vapour deposition (PVD).
For the thermal oxidation, there are dry type and wet type: the dry type uses the
reaction Si+O2 → SiO2 and usually serves as gate oxide; while the wet type uses reaction
Si+2H2O → SiO2+2H2 and usually serves as field oxide/diffusion barrier. Also, during
the silicon-silicon dioxide interface moves into the silicon during this process.
Figure 2.1: Thermal Oxidation
3
For the CVD, this process uses chemical reaction of a gas mixture to deposit a solid
firm and usually used in depositing conformal. Also, it uses an energy source to break
reactant gases into reactive species for deposition.
(a) NOR gate (b) NOT gate
Figure 2.2: CVD
For the PVD, the first stage is evaporation where the materials to be deposited is
heated to a high vapor pressure; the second stage is sputtering where some materials were
sputtered away for subsequent deposition without any chemical reaction.
Figure 2.3: PVD
Photolithography
The subsequent step is photolithography and etching. For the photolithography stage:
a layer that is sensitive to ultraviolet (UV) radiation is put on the wafer and then this
coated wafer is placed in an illumination system shining UV radiation through a lens mask.
The etching removes materials selectively.
Figure 2.4: UV Exposure
4
Doping
This step has two stage: first is the thermal diffusion where dopant gases are fisted
diffused into silicon and then turned off using silicon dioxide; and second is ion implan-
tation where damaged region and non-saturation location are caused. The implantation
stage possesses advantages including precise control of dose and depth profile, with low
temperature and allow wide selection of materials.
(a) NOR gate (b) NOT gate
Figure 2.5: Dopant Diffusion
nMOS Fabrication
This primarily consists of the four mask manufacture. First, the thermal oxidation
was applied to build SiO2 layer upon a p-type silicon bulk. Then, Mask one was added
to form the Active region and then, the top is coated with an oxide layer and a poly-Si
layer is subsequently placed using CVD. Then a gate layer is added as a Mask two after
one more oxide layer. Next, it is exposed to the UV to be etched so as to be ready for
being doped with n-type. Subsequently, the contact hole layer is placed as a Mask three
after one more oxide layer added. Finally Mask four is established by taking away some
sections of the just placed metal layer.
IC Resistor Fabrication
P-type silicon is used as substrate, and a thin oxide layer is placed onto the wafer.
Then a n-type doped region is created using ion implantation, and another oxide layer
is added after which the contact hole mask is placed. finally, the metal mask is used to
pattern the metal after a metal layer is added.
Figure 2.6: IC Resistor
5
2.2 Procedure
2.2.1 Logic Date Truth Table
The Boolean Expression of NOR gate is that OUT = A+B, while the expression of
the NOT gate is that OUT = A.
Therefore, by combining these two gates, we can obtain their output relation thus
derive the relationship between the “OUT” in this particular project and the inputs A
and B. The Truth Table of this logic gates composed of a NOR gate and a NOT gate in
series is presented below, where 0 stands for LOW and 1 stands for HIGH.
Table 2.1: Truth Table
A B C OUT
0 0 1 00 1 0 11 0 0 11 1 0 1
2.2.2 Parameter Calculation
Aspect Ratio of NOR
(a) NOR gate (b) NOT gate
As can be seen in Figure above, in the NOR gate circuit, for both transistor A and
transistor B, when their VDD = Vin = 5V (High), the output voltage VOUT is expected to
be Low due to the working principle of NOR gate. In this case of detailed calculation, we
set VOUT = 0.1V , which is less than the threshold voltage VTH = 0.3V .
6
Subsequently, based on these assumptions and the rule of voltage division, the equiv-
alent resistance of transistor channel can be obtained:
VOUT
VDD=
RD
RD +RL(2.1)
Solving the equation above, we obtained RD = 100Ω.
Then, we worked on the drain current ID. First, we decided that the mode is “non-
saturation” mode by observing that the drain-source voltage is in the same potential
level with that of the output voltage VOUT , which has been assumed to be 0.1V, thus
Vg − VT = 5− 0.3 = 4.7V > VOUT = VD must be correct.
Therefore, according to the learnt formula for calculating the drain current, we obtain:
ID = β0 ×W
L[(Vg − VT )VOUT − VOUT
2
2] (2.2)
Also, by analysing the circuit configuration, it can be obtained that:
RD =VOUT
ID(2.3)
Grouping the above two equations 2.2 and 2.3, and solving, we obtained that the aspect
ratio for both two transistor A and B are all WL ≈ 12
Aspect Ratio of NOT
The aspect ratio calculated for transistors in NOR gate could be also utilized here in
inverter for the lower transistor as well. While for the Load transistor L, its drain-source
voltage VDS can be obtained:
VDS = VDD − VOUT (2.4)
Solving the above equation, we obtained that VDS = 4.9V , which is bigger than the
saturation voltage Vsat which is 4.7V. Therefore, the transistor L is also in “saturation”
mode. Thus we obtained the drain current using formula:
ID = β0 ×W
L× Vsat
2
2= 1mA (2.5)
Solving the above equation, we obtained that WL ≈ 0.5
Resistor
Finally, for the resistor, since it has a resistance of 5kΩ, the sheet resistance can be
obtained is 100Ω/sq. Then we worked out the length-width ratio of it:
R =L
WRS = 5kΩ (2.6)
We obtained that LW = 50.
7
2.2.3 Mask Drawing with Design Rule
The process of drawing the layout graph was first simulated using software named
L-Edit to help observing all the distances among sections clearly so as to ensure that the
design can strictly agree with the Design Rule List. The masks graph drawn using software
are presented below.
(c) NOR gate (d) NOT gate
(e) NOR gate (f) NOT gate
Then, real drawing of the layout was conducted. Each smallest grid of that coordinate
paper was regarded as 1λ, and each mask used 52× 25 numbers of grids. The pictures of
graphs can be seen in Appendix A.
8
Section 3
Discussion
3.1 Outcome Layout
Figure 3.1: The Layout
Minimization
During the drawing, the width was minimized as much as possible by for example
setting the distance of contacts with adjacent poly edge to the minimum distance to
achieve the goal of minimize the size of layout.
Also, for the resistor, one terminal of it did not consume contact but saves the space
by being connected with the active area directly.
9
Practical Approximation
However, for the metal, the mask was not designed to be all in the minimum size since
in the fabrication stage, metal mask is obtained by removing some part selectively and
the cost of using slightly thinker or longer metal bar is not much thus the design of metal
took the connection clarity and effectiveness as the top priority rather than simply the
size.
Also, for the resistor design, the real drawing of the resistor is 51 grids rather than 50
as calculated. This is to protect the circuit and ensure the clarity of the shape of the layout
(avoid strange shape of resistor) since this slightly larger resistor can cause an output that
is slightly less than 0.1V which still logically effective in this case.
3.2 Worst Case Anslysis
When we set the VOUT of NOR gate, we first knew that this should be smaller than
the threshold voltage VT which is 0.3V since the High or LOW is decided with regard to
the VT in this logic system. Therefore, the VOUT should be set less enough than the VT .
Then, we verify the real situation by setting the NOR VOUT to be Vc. By varying the
value of Vc from 0.01V to 0.1. The worked out corresponding value of aspect ratio using
the same method of that used in previous parameter calculation section was found to be
increasing with the increase of the Vc.
However, if the VOUT is set too small thus much smaller than the worst case situation,
the aspect ratio would be high thus increase the cost. Therefore, the set VOUT should be
close to the one that meets the worst case.
Practically, the “worst case” is where the NOR gate inputs are a 1(HIGH) and 0(LOW)
respectively. When the Vb and Va (inputs A and B) are all High, the calculated aspect
ratio is 6, while when these two are a High and a Low, the calculated aspect ratio is 12
which is the worst case. Thus 0.1V should be a suitable value since it is not too large to
break the circuit function nor too small to increase the cost.
10
Section 4
Conclusion
4.1 Achievement
To conclude, this project deepened the understanding of the manufacturing processes
of the MOS-based device and the calculations principles to obtain the aspect ratio for
logic gates components. In this particular case, the aspect ratios of three MOS were are
12 while the load transistor ratio was calculated specially to be 0.5. After comprehensive
verification using calculation and worst case analysis, it has been observed that increasing
the (W/L) will decrease the output voltage.
Here, we set the
4.2 Limitation and Suggestion
One limitation of this project is that the layout pattern is quite fundamental without
quite advanced minimization such as combing two parallel nMOS together in one body.
This was because that the drawing was conducted in a hurry without comprehensive on-
line searching about the technique of minimizations that were not limited to those learnt
in classes or set by Design Rule List.
The corresponding future suggestion of this case is that source searching and enough
interaction with teachers about intention of trying new techniques should be done before
actually getting down to the task.
11
Appendix A
Graph
A.1 Layout
Figure A.1: The Layout
Figure A.2: The Scale Indication
12
A.2 Masks
Mask One
Figure A.3: Mask One
Mask Two
Figure A.4: Mask Two
13
Mask Three
Figure A.5: Mask Three
Mask Four
Figure A.6: Mask Four
14
Reference
[1] EEE112 Integrated Electronics and Design nMOS IC Design Project, XJTLU
[2] IC Fabrication Techniques Layouts: revision, XJTLU
15
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