CS代考 Integrated Electronics & Design

Integrated Electronics & Design
nMOS logic IC design
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⚫ NMOSlogic(examples) ⚫ Calculation
⚫ DesignExercise

Transistor in Linear Mode VD
Assuming V
n+ – V(x) +
VGS-VT VDS
T : ID = b0 W/L [(VGS – VT)VDS – VDS2/2]
b0 = nCox
R = VDS / ID

Transistor in Saturation Mode
Assuming V
VDS > VGS – VT
n+ – VGS – VT + n+ Pinch-off
: ID = (b0/2) W/L [(VGS – VT) 2]

NMOS Logic (Inverter): Example 1
Calculate W/L with the following specification: -4 -2
1) RL=5k. 2) b= b0(W/L), and b0= 1.8*10 AV . 3) VT =0.3V. 4) VDD=5V.
The aspect ratio, W/L, is ??
Layout(版图)

NMOS Logic (Inverter): Example 1
Calculate W/L with the following specification: 1) RL=5k. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT =0.3V. 4) VDD=5V.
If Vin = VDD, let VOut = 0.1V << VT Potential divider: RD/(RD+RL)=VOut/VDD=0.1/5=0.02 → RD ≈ 100 ID= b[(VG-VT)VD-VD2/2]  b[(VG-VT)VD] RD= VOut/ID ={b[(VDD-VT)]}-1 =1/[b(5-0.3)]=100 → b ≈ 20*10-4. Therefore, the aspect ratio, W/L, is 12. NMOS Logic (Inverter): Example 1 Calculate W/L with the following specification: 1) RL=5k. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT =0.3V. 4) VDD=5V. NMOS Logic (Inverter): Example 1 Calculate W/L with the following specification: 1) RL=5k. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT =0.3V. 4) VDD=5V. NMOS Logic (Inverter): Example 2 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 12. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. =24 L =2 NMOS Logic (Inverter): Example 2 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 12. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. If Vin = VDD, let VOut = 0.1V: ID = bD[(Vin-VT)VOut-VOut2/2] RD= VOut/ID =(12b0[(VDD-VT)])-1 =100  [RD/(RD+RL)]=VOut/VDD=0.1/5=0.02 ID =bL(VDD -VT)2/2 R = (V -V )/I = 4.9*2/[b (5-0.3)2] =5k LDDoutD L → bL = 8.9*10-5 → aspect ratio of load = 0.5 NMOS Logic (Inverter): Example 2 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 12. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. W/L of Load= 0.5 NMOS Logic (Inverter): Example 2 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 12. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. NMOS Logic (NOR): Example 3 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 12. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. R Solution: L let VOut = 0.1V: ID = bD[(VinA-VT)VOut-VOut2/2] RD= VOut/ID =(bD[(VDD-VT)])-1 =100  [0.5RD/(0.5RD+RL)]=VOut/VDD=0.1/5=0.02 → RL=2.5k ID =bL(VDD -VT)2/2 R = (V -V )/I = 4.9*2/[b (5-0.3)2] =2.5k LDDoutD L → bL =1.8*10-4 → aspect ratio of Load= 1. Example: Design Exercise 1 ➢ ➢ ➢ ➢ ➢ ➢ It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq W/L = 12/1 Example: Design Exercise 2 Layout design of the NMOS IC ➢ ➢ ➢ ➢ ➢ ➢ It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq NMOS Logic (NOR): Example 4 Calculate W/L with the following specification: 1) RL=5k. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT =0.3V. 4) VDD=5V. If VA=VB=VDD, let VOut = 0.1V << VT Potential divider: 0.5RD/(0.5RD+RL)=VOut/VDD=0.1/5=0.02 → RD ≈ 200 ID= b[(VG-VT)VD-VD2/2]  b[(VG-VT)VD] RD=VOut/ID={b[(VDD-VT)]}-1 =1/[b(5-0.3)]=200 → b ≈ 10*10-4. Therefore, the aspect ratio, W/L, is Example: Design Exercise 2 Layout design of the nMOS IC shown in Fig.1 ➢ ➢ ➢ ➢ ➢ ➢ It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq NMOS Logic (Inverter): Example 5 Calculate W/L of Load with the following specification: 1) The aspect ratios of D is 6. 2) b= b0(W/L), and b0= 1.8*10-4AV-2. 3) VT = 0.3V. 4) VDD=5V. If Vin = VDD, let VOut = 0.1V: ID = bD[(Vin-VT)VOut-VOut2/2] RD= VOut/ID =(6b0[(VDD-VT)])-1 =200  [RD/(RD+RL)]=VOut/VDD=0.1/5=0.02 → RL ≈ 10k ID =bL(VDD -VT)2/2 R = (V -V )/I = 4.9*2/[b (5-0.3)2] =10k LDDoutD L → bL = 4.4*10-5 → aspect ratio of load = 0.25 Example: Design Exercise 2 Layout design of the nMOS IC shown in Fig.1 ➢ ➢ ➢ ➢ ➢ ➢ It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq W=4, L=16 ⚫ NMOSlogic(examples) ⚫ Calculation ⚫ DesignExercise NMOS Logic (Inverter): Example 1 5K NMOS Logic (Inverter): Example 1 5K For small LR/WR: (e.g. LR/WR=9) For large LR/WR: (e.g. LR/WR=20) Squares are used to calculate the length, L. 22 NMOS Logic (Inverter): Example 1 For small LR/WR: (e.g. LR/WR=9) For large LR/WR: (e.g. LR/WR=20) Every square must disappear when drawing your layout NMOS Logic (Inverter): Example 1 5K NMOS Logic (Inverter): Example 1 5K Active mask for n+ region NMOS Logic (Inverter): Example 1 RL=5k & Rs=100/sq RL=Rs(LR/WR) → LR/WR=50 NMOS Logic (Inverter): Example 2 W/L VDD Aluminium Load device via to VDD Polysilicon gate of load MOSFET with a via to Aluminium and VDD Drain of driver with a via to output Source Via to load MOSFET polysilicon gate as input to circuit Source of driver with a via Ground line (Aluminium) NMOS Logic (Inverter): Example 2 Mask1 NMOS Logic (Inverter): Example 2 Mask2 NMOS Logic (Inverter): Example 2 Mask3 NMOS Logic (Inverter): Example 2 Mask4 NMOS Logic (Inverter): Example 2 VDD Aluminium Load device via to VDD Drain of driver with a via to output polysilicon gate as input to circuit Source of driver with a via Ground line (Aluminium) Polysilicon gate of load MOSFET with a via to Aluminium and VDD Source Via to load MOSFET NMOS Logic (NOR): Example 3 ⚫ NMOSlogic(examples) ⚫ Calculation ⚫ DesignExercise Example: Design Exercise 2 Layout design of the nMOS IC shown in Fig.1 ➢ ➢ ➢ ➢ ➢ ➢ It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq Example: Design Exercise 2 ⚫ Design rules: ⚫ The driver transistors should have channel length L equal to the minimum feature size m. The width of the drivers W, which must always be a whole number (n) of minimum feature sizes (nm), and the overall value of W must be chosen to give the required output voltage. This must be significantly less than the threshold voltage of the third gate C if this transistor is to stay off. ⚫ The layouts must take account of the alignment accuracy a. W/L=6 W/L=6 Example: Design Exercise 2 1) The Design involves producing the patterns corresponding to each of the stages of the process already discussed. 2) Each of the patterns should be drawn on graph paper with a stipulated scale. (e.g 1m per cm.) 3) The patterns would be transferred at a later stage to glass masks, as opaque regions. There are 4 masks : M1. define the device area (active) M2. define the gate stripe (poly) M3. define the contacts (contact) M4. define the metal pattern (metal) Example: Design Exercise 1 It consists of an n channel NOR gate feeding an inverter. The transistors A and B are the termed driver MOSFETs. The process parameters are defined: b0 = 1.8×10-4AV-2 VT = 0.3V VDD=5V RS = 100/sq HINTS: Liverpool notes. ➢ ➢ ➢ ➢ ➢ ➢ W/L = 12/1 程序代写 CS代考 加微信: powcoder QQ: 1823890830 Email: powcoder@163.com