The characteristics and operation of pass NMOS and PMOS transistor logic. The characteristics and operation of CMOS transmission gate logic. The resistance behavior for both logic
Theory A conceptually simple approach for implementing logic functions utilizes series and parallel combinations of switches that are controlled by input logic variables to connect the input and output nodes. Each of the switches can be implemented either by a single NMOS transistor (Fig. 1 known as pass-transistor logic (PTL)) or by a pair of complementary MOS transistors connected in what is known as the CMOS transmission-gate configuration (Fig. 2). The pass transistor logic reduces the number of transistors required to implement the logic. NMOS transistors pass a strong 0 but a weak 1(threshold voltage drop. High =Vdd-Vtn) and PMOS transistors pass a strong 1 but a weak 0(threshold voltage drop. Low= Vtp)
Fig. 1: Pass transistor
Fig. 2: Transmission gate
Also the pass transistor logic can not be cascaded as shown in Fig.3 but can be cascaded as shown in Fig. 4.
1
2
Spice model for the NMOS transistor in the laboratory is: .model MbreakN-X NMOS LEVEL=2 LD=0.250000U TOX=417.000008E-10 + NSUB=6.108619E+14 VTO=1.2 KP=500u GAMMA=2.2 + PHI=0.6 UO=594 UEXP=6.682275E-02 UCRIT=5000 + DELTA=5.08308 VMAX=65547.3 XJ=0.250000U LAMBDA=0.01 + NFS=1.98E+11 NEFF=1 NSS=1.000000E+10 TPG=1.000000 + RSH=32.740000 CGDO=3.105345E-10 CGSO=3.105345E-10 CGBO=3.848530E-10 + CJ=9.494900E-05 MJ=0.847099 CJSW=4.410100E-10 MJSW=0.334060 PB=0.800000 2.0V
1.5V
1.0V
0.5V
0V 0V
0.5V
1.0V
3.0V
2.5V
2.0V
1.5V
3.5V
4.0V
4.5V
5.0V
V(M3:d) V_VIN
Vout versus Vin for NMOSFET pass transistor 5.0K 2.0M
4.0K 1.5M
3.0K
1.0M
2.0K
0.5M
1.0K
0 0V
0.5V 1.0V ABS((V1(VIN)-V(R4:1))/I(VIN))
1.5V
2.0V
2.5V
3.0V
3.5V
4.0V
V_VIN
Resistance of NMOSFET vs. VIN
4.5V
5.0V
0 0V
0.2V 0.4V ABS((V1(VIN)-V(R4:1))/I(VIN))
0.6V
0.8V
1.0V
1.2V
1.4V
1.6V
1.8V
V_VIN
Ron of NMOSFET vs. VIN
The solution of the output signal loss is solved by connecting the output node of the PTL to the input of CMOS inverter. A PMOS transistor QR whose gate is controlled by the output of the inverter and its drain connected to the output of the PTL as shown A3 in the discussion. Great improvements in static and dynamic performance are obtained when the switches implemented with CMOS transmission gates. The transmission gate utilizes a pair of 3
complementary transistors connected in parallel. It acts as an excellent switch, providing bidirectional current flow (Fig. 5), and it exhibits an on-resistance that remains almost constant for wide ranges of input voltage. These characteristics make the transmission gate not only an excellent switch in digital applications but also an excellent analog switch in such applications data converters and switched-capacitor filters.
4
5
5.0V
4.0V
3.0V
2.0V
1.0V
0V 0V
0.5V
1.0V
1.5V
2.0V
2.5V
3.0V
3.5V
4.0V
4.5V
5.0V
V(R4:2) V_V1
Vout versus Vin for Transmission Gate
6
Experimentally
CD4407 PARTS AND MATERIALS • • •
CD4007 MOSFET gate. Pro board power supply. Semiconductor Parameter Analyzer hp 4145B A) NMOS Pass Transistor Logic
For figure 1: 1234-
Fig. 1:
Select an NMOSFET from the CD4007. Set VA to 5V. Change VIN from 0 to 5V IN STEP of 0.25V. Measure the output voltage and the input current in list. B) Transmission Gate Logic.
For figure 2: 5- Set VA to 5V. 6- Change VIN from 0 to 5V IN STEP of 0.25V. 7- Measure the output voltage and the input current in list.
Fig. 2: 7
Discussion: For figure 1: 1- Plot the experimental Vo versus VIN. 2- Using SPICE plot Vo versus VIN. 3- From the experimental part, calculate the NMOSFET resistance at the different values of VIN. 4- Plot the calculated resistance versus Vin 5- Plot the on resistance only versus corresponding Vin 6- Using SPICE plot the resistance R and Ron of NMOS versus VIN 7- Comment on the plot. For figure 2: 8- Plot the experimental Vo versus VIN. 9- Using SPICE plot Vo versus VIN. 10- From the experimental part, calculate the Transmission gate resistances at the different values of VIN. 11- Plot the calculated resistances versus Vin. 12- Using SPICE plot the resistance of Transmission Gate versus VIN and compare with experimental one. Spice model for the PMOS transistor in the laboratory is: .model MbreakP-X PMOS LEVEL=2 LD=0.227236U TOX=417.000008E-10 + NSUB=1.056124E+16 VTO=-1.2 KP=600u GAMMA=0.5 + PHI=0.6 UO=209 UEXP=0.233831 UCRIT=47509.9 + DELTA=1.07179 VMAX=100000 XJ=0.250000U LAMBDA=.05 + NFS=3.27E+11 NEFF=1.001 NSS=1.000000E+10 TPG=-1.000000 + RSH=72.960000 CGDO=2.822585E-10 CGSO=2.822585E-10 CGBO=5.292375E-10 + CJ=3.224200E-04 MJ=0.584956 CJSW=2.979100E-10 MJSW=0.310807 PB=0.800000