MALVINO

1. SIXTH EDITION MALVINO Electronic PRINCIPLES

2. Negative Feedback Chapter 19

3. Amplifier possibilities • The input can be a voltage. • The input can be a current. • The output can be a voltage. • The output can be a current. • The total number of combinations is four.

4. Four types of negative feedback • Voltage-controlled voltage source (VCVS) (ideal voltage amplifier) • Current-controlled voltage source (ICVS) (transresistance amplifier) • Voltage-controlled current source (VCIS) (transconductance amplifier) • Current-controlled current source (ICIS) (ideal current amplifier)

5. Converters • VCIS and ICVS amplifiers can be viewed as converters. • The VCIS is often called a voltage-to-current converter. • The ICVS is often called a current-to-voltage converter.

6. VCVS equivalent circuit Low zout High zin vin vout AVvin The input impedance is very high and the output impedance is very low. It approaches the ideal voltage amplifier.

7. ICVS equivalent circuit Low zout iin Low zin vout rmiin The input impedance is very low and the output impedance is very low. It is well suited for converting a current into a voltage (rm is the transresistance).

8. VCIS equivalent circuit iout High zout High zin vin gmvin The input impedance is very high and the output impedance is very high. It is well suited for converting a voltage into a current (gm is the transconductance).

9. ICIS equivalent circuit iin iout High zout Low zin Aiiin The input impedance is very low and the output impedance is very high. It approaches the ideal current amplifier.

10. R2 R1 1 = +1 B v2 The feedback fraction B = vout 1 @ B AOL ACL = 1 +AOLB The noninverting circuit is a VCVS amplifier. vout vin R2 v2 R1 The term AOLB is called the loop gain and is normally much greater than 1.

11. The loop gain is usually very large which provides: • Gain stability • Low distortion • Low offsets • Near ideal input impedance • Near ideal output impedance

12. zin(CL) = (1+AOLB)Rin RCM Input impedance of the noninverting amplifier vout vin R2 R1 (RCM > 100 MW for a 741) Rin = the open-loop input resistance of the op amp RCM = the common-mode input resistance of the op amp

13. zout(CL) = Rout 1 + AOLB Output impedance of the noninverting amplifier vout vin R2 R1 (Rout = 75 W for a 741) Rout = the open-loop output resistance of the op amp

14. Distortion • A sine wave has only one frequency called the fundamental. • An amplifier with distortion adds energy at new frequencies called harmonics. • Total harmonic distortion (THD) is the percentage of harmonic voltage in the output signal. • THD = (Total harmonic voltage/fundamental voltage) x 100%

15. THDOL THDCL = 1 + AOLB THD of the noninverting amplifier vout vin R2 R1

16. Rout R zout(CL) = zin(CL) = 1 + AOL AOL 1 + AOL @ iin R vout = iin R 1 +AOL The ICVS amplifier R R is the transresistance vout iin

17. R2is the load vin R1 + R2 @ R1 AOL iout = gm vin vin 1 iout = transconductance: gm = zin(CL) = (1+AOLB)Rin zout(CL) = (1+AOL)R1 R1 R1 + The VCIS amplifier vin R2 iout R1

18. Ai = R2 @ R2 + 1 R1 AOL(R1+R2) R1 zin(CL) = B = 1+AOLB R1+R2 RL+AOLR1 The ICIS amplifier iin RL iout R2 R1 zout(CL) = (1+AOL)R1

19. VCVS bandwidth • Negative feedback increases the bandwidth of an amplifier. • Less voltage is fed back at the higher frequencies due to rolloff which effectively increases the input signal. • An equation for closed-loop bandwidth: f2(CL) = (1+AOLB)f2(OL) • The gain-bandwidth product is constant: ACLf2(CL) = funity

20. Slew-rate distortion • Negative feedback has no effect. • The op amp is not acting in the linear mode so the feedback doesn’t help. • Even though the small-signal bandwidth might be adequate, the power bandwidth might not. • Independent calculations of both bandwidths are required to ensure adequate performance.