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PowerPoint Overheads to Accompany Sedra/Smith Microelectronic Circuits 4/e ©1999 Oxford University Press. Microelectronic Circuits - Fourth Edition Sedra/Smith 0 Fig. 13.2 Typical voltage transfer characteristic (VTC) of a logic inverter, illustrating the definition of the critical points. Microelectronic Circuits - Fourth Edition Sedra/Smith 1 Fig. 13.3 Definitions of propagation delays and switching times of the logic inverter. Microelectronic Circuits - Fourth Edition Sedra/Smith 2 Fig. 13.4 (a) The CMOS inverter and (b) its representation as a pair of switches operated in a complementary fashion. Microelectronic Circuits - Fourth Edition Sedra/Smith 3 Fig. 13.5 The voltage transfer characteristic (VTC) of the CMOS inverter when QN and QP are matched. Microelectronic Circuits - Fourth Edition Sedra/Smith 4 Fig. 13.12 A two-input CMOS NOR gate. Microelectronic Circuits - Fourth Edition Sedra/Smith 5 Fig. 13.13 A two-input CMOS NAND gate. Microelectronic Circuits - Fourth Edition Sedra/Smith 6 Fig. 13.16 Proper transistor sizing for a four-input NOR gate. Note that n and p denote the (W/L) rations of QN and QP, respectively, of the basic inverter. Microelectronic Circuits - Fourth Edition Sedra/Smith 7 Fig. 13.17 Proper transistor sizing for a four-input NAND gate. Note that n and p denote the (W/L) rations of QN and QP, respectively, of the basic inverter. Microelectronic Circuits - Fourth Edition Sedra/Smith 8 Fig. 13.21 VTC for the pseudo-NMOS inverter. This curve is plotted for VDD = 5, Vtn = -Vtp = 1 V, and r = 9. Microelectronic Circuits - Fourth Edition Sedra/Smith 9 Fig. 13.33 (a) basic structure of dynamic-MOS logic circuits; (b) waveform of the clock needed to operate the dynamic-logic circuit; and (c) an example circuit. Microelectronic Circuits - Fourth Edition Sedra/Smith 10 Fig. 13.34 (a) Charge sharing. (b) Adding a permanently turned-on transistor QL solves the charge-sharing problem at the expense of static-power dissipation. Microelectronic Circuits - Fourth Edition Sedra/Smith 11 Fig. 13.35 Two single-input dynamic-logic gates connected in cascade. With the input A high, during the evaluation phase CL2 will partially discharge and the output at Y2 will fall lower than VDD, which can cause logic malfunction. Microelectronic Circuits - Fourth Edition Sedra/Smith 12 Fig. 13.37 (a) Two single-input DOMINO CMOS logic gates connected in cascade. (b) Waveforms during the evaluation phase. Microelectronic Circuits - Fourth Edition Sedra/Smith 13 Fig. 13.38 (a) Basic latch. (b) The latch with the feedback loop opened. (c) Determining the operating point of the latch. Microelectronic Circuits - Fourth Edition Sedra/Smith 14 Fig. 13.40 CMOS implementation of a clocked SR flip-flop. The clock signal is denoted by . Microelectronic Circuits - Fourth Edition Sedra/Smith 15 Fig. 13.42 A simpler CMOS implementation of the clocked SR flip-flop. This circuit is popular as the basic cell in the design of static random-access memory chips. Microelectronic Circuits - Fourth Edition Sedra/Smith 16 Fig. 13.44 A simple implementation of the D flip-flop. The circuit in (a) utilizes the two-phase nonoverlapping clock whose waveforms are shown in (b). Microelectronic Circuits - Fourth Edition Sedra/Smith 17 Fig. 13.45 (a) A master-slave D flip-flop. Note that the switches can be, and usually are, implemented with CMOS transmission gates. (b) Waveforms of the two-phase nonoverlapping clock required. Microelectronic Circuits - Fourth Edition Sedra/Smith 18 Fig. 13.47 Monostable circuit using CMOS NOR gates. Signal source vI supplies the trigger pulses. Microelectronic Circuits - Fourth Edition Sedra/Smith 19 Fig. 13.50 Timing diagram for the monostable circuit in Fig. 13.47. Microelectronic Circuits - Fourth Edition Sedra/Smith 20 Fig. 13.52 (a) A simple astable multivibrator circuit using CMOS gates. (b) Waveforms for the astable circuit in (a). The diodes at the gate input are assumed ideal and thus limit the voltage vI1 to 0 and VDD. Microelectronic Circuits - Fourth Edition Sedra/Smith 21 Fig. 13.53 (a) A ring oscillator formed by connecting three inverters in cascade. (Normally at least five inverters are used.) (b) The resulting waveform. Observe that the circuit oscillates with frequency 1/(6tp). Microelectronic Circuits - Fourth Edition Sedra/Smith 22 Fig. 13.54 A 2M+N-bit memory chip organized as an array of 2M rows x 2N columns. Microelectronic Circuits - Fourth Edition Sedra/Smith 23 Fig. 13.55 A CMOS SRAM memory cell. Microelectronic Circuits - Fourth Edition Sedra/Smith 24 Fig. 13.60 A differential sense amplifier connected to the bit lines of a particular column. This arrangement can be used directly for SRAMs (which can utilize both B and B lines). DRAMs can be turned into differential circuits by using the “dummy cell” arrangement shown in Fig. 13.61. Microelectronic Circuits - Fourth Edition Sedra/Smith 25 Fig. 13.61 Waveforms of vB before and after activating the sense amplifier. In a read-1 operation, the sense amplifier causes the initial small increment V(1) to grow exponentially to VDD. In a read-0 operation, the negative V(0) grows to 0. Complementary signal waveforms develop on the B line. Microelectronic Circuits - Fourth Edition Sedra/Smith 26 Fig. 13.62 Arrangement for obtaining differential operation from the single-ended DRAM cell. Note the dummy cells at the far right and far left. Microelectronic Circuits - Fourth Edition Sedra/Smith 27 Fig. 13.63 A NOR address decoder in array form. One out of eight lines (row lines) is selected using a 3-bit address. Microelectronic Circuits - Fourth Edition Sedra/Smith 28 Fig. 13.64 A column decoder realized by a combination of a NOR decoder and a pass-transistor multiplexer. Microelectronic Circuits - Fourth Edition Sedra/Smith 29 Fig. 13.65 A free column decoder. Note that the colored path shows the transistors that are conducting when A0 = 1, A1 = 0, and A2 = 1, the address that results in connecting B5 to the data line. Microelectronic Circuits - Fourth Edition Sedra/Smith 30 Fig. 13.66 A simple MOS ROM organized as 8 words x 4 bits. Microelectronic Circuits - Fourth Edition Sedra/Smith 31 Fig. 13.67 (a) Cross section and (b) circuit symbol of the floating-gate transistor used as an EPROM cell. Microelectronic Circuits - Fourth Edition Sedra/Smith 32 Fig. 13.68 Illustrating the shift in the iD-vGS characteristic of a floating-gate transistor as a result of programming. Microelectronic Circuits - Fourth Edition Sedra/Smith 33 Fig. 13.69 The floating-gate transistor during programming. Microelectronic Circuits - Fourth Edition Sedra/Smith 34 Fig. 14.1 Switching times of the BJT in the simple inverter circuit of (a) when the input v1 has the pulse waveform on (b). The effects of stored base charge following the return of v1 to V1 are explained in conjunction with Eqs. (14.2) and (14.3). Microelectronic Circuits - Fourth Edition Sedra/Smith 35 Fig. 14.20 Analysis of the TTL gate with the input high. The circled numbers indicate the order of the analysis steps. Microelectronic Circuits - Fourth Edition Sedra/Smith 36 Fig. 14.22 Analysis of the TTL gate when the input is low. The circled numbers indicate the order of the analysis steps. Microelectronic Circuits - Fourth Edition Sedra/Smith 37 Fig. 14.23 The TTL gate and its voltage transfer characteristic. Microelectronic Circuits - Fourth Edition Sedra/Smith 38 Fig. 14.24 The TTL NAND gate. Microelectronic Circuits - Fourth Edition Sedra/Smith 39 Fig. 14.25 Structure of the multiemitter transistor Q1. Microelectronic Circuits - Fourth Edition Sedra/Smith 40 Fig. 14.28 A Schottky TTL (known as STTL) NAND gate. Microelectronic Circuits - Fourth Edition Sedra/Smith 41 Fig. 14.33 Basic gate circuit of the ECL 10K family. Microelectronic Circuits - Fourth Edition Sedra/Smith 42 Fig. 14.35 Simplified version of the ECL gate for the purpose of finding transfer characteristics. Microelectronic Circuits - Fourth Edition Sedra/Smith 43 Fig. 14.36 The OR transfer characteristic vOR versus v1, for the circuit in Fig. 14.35. Microelectronic Circuits - Fourth Edition Sedra/Smith 44 Fig. 14.38 The NOR transfer characteristic, vNOR versus v1, for the circuit in Fig. 14.35. Microelectronic Circuits - Fourth Edition Sedra/Smith 45 Fig. 14.44 Development of the BiCMOS inverter circuit: (a) The basic concept is to use an additional bipolar transistor to increase the output current drive of each QN and QP of the CMOS inverter; (b) the circuit in (a) can be thought of as utilizing these composite devices; (c) to reduce the turn-off times of Q1 and Q2, “bleeder resistors” R1 and R2 are added; (d) implementation of the circuit in (e) using NMOS transistors to realize the resistors; (e) an improved version of the circuit in (c) obtained the lower end of R1 to the output mode. Microelectronic Circuits - Fourth Edition Sedra/Smith 46