Advanced Circuit Techniques (55:141)
Spring 2012
Midterm Exam Score:
/70
Name: _____________________ _____________________
Question 1 (1 point unless unless noted otherwise) otherwise)
1.
. Neglecting losses and assuming CCM ? (4 points)
A buck converter has and and operation, what is and the load current Answer
. , so that ⁄ ⁄ 2.
Assume a buck DC/DC converter with no feedback control. What is the steady-state mean output voltage if the converter is in CCM?
(b) ⁄ Answer so (a) (a)
3.
(c)
⁄
(d)
The input voltage to a lossless DC/DC regulator doubles, doubles , but the load stays the same. The input current will (a) Double
(b) Half
(c) Stay the same
(d) Depends on the type of converter
Answer (b)
4.
Consider a switched-capacitor voltage-inverter where . The “flying” capacitor’s value is halved. Then, because half as much charge is transferred during durin g every cycle, the output voltage will (a) Half
(b) Decrease by factor 4 (c) Stay the same
(d) Need additional information
Answer: (c)
5.
Consider a switched-capacitor voltage-inverter where . The switching frequency is doubled. Then, because twice as much charge is transferred per unit time, the output voltage will (a) Double
(b) Quadruple
(c) Stay the same
(d) Need additional information
Answer: (c)
6.
When researching part numbers for three-terminal regulators, an engineer encounters the term “LDO”. What does “LDO” stand for? Answer: “Low Drop Out”
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Advanced Circuit Techniques (55:141)
7.
The duty cycle for the switch in the DC/DC converter below is lossless operation, is (a)
(b)
⁄
(c)
Spring 2012
. The output voltage, assuming
⁄
(d) None of (a) – (c)
Answer: This is a buck DC/DC converter so that (a) is the correct answer.
8.
Briefly explain why semiconductor companies often specify the ripple rejection ratio of their threeterminal regulators at frequencies in the range 100 — 120 Hz. Why is it important to know the ripple rejection at these particular frequencies?
Answer: When full-wave bridge rectifiers rectify 50 Hz (i.e., Europe) or 60 Hz (i.e., U.S.) ac, the resulting ripple frequency is 100 — 120 Hz, so the regulator must remove these ripple voltages.
9.
The smoothing capacitor in a linear regulator is replaced with a capacitor that has twice the value. The load current stays the same. The peak current through the rectifier diodes will then (a) Increase
(b) Stay the same
(c) Decrease
Answer: (a)
10.
Consider the steady-state (i.e., no inrush current) peak diode current in a linear power supply. For a load current , the peak diode current can be as large as (pick the largest reasonable value):
(a) Answer (b)
11.
(b) 20
(c) 100
(6) 1,000
A buck DC/DC converter with no feedback is in CCM. The load is then removed. The new steadystate mean output voltage will then (assuming lossless operation and duty cycle D) be (a)
(b)
(c)
(d)
Answer (b)
12.
Identify the serious flaw in the circuit. Answer: There is no smoothing capacitor.
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Advanced Circuit Techniques (55:141)
Spring 2012
Question 2 Explain how one can use a +5 V three-terminal regulator to regulate for . For example, how can one use a +5 V regulator as a +12 V regulator? Provide a diagram, and an equation for the output voltage. You don’t have to specify component (i.e., resistor) values. (6 points) Solution
Add two external resistors as shown. Then
( )
Note:
must always be included, but many people omitted this.
Question 3
(a) Explain is 4 – 5 sentences what a gated oscillator dc/dc converter is. (3 points) (b) Name one advantage of such converters. (1 point) (c) Name one disadvantage of such converters. (1 point) Solution
(a) In a gated oscillator dc/dc converter, the oscillator controls the energy-conversion switch. The output voltage is measured and compared against a reference. If the output voltage exceeds the reference, the oscillator is turned off. If the output voltage falls below the reference, the oscillator is turned on again. The oscillator has fixed frequency and duty cycle. (b) One advantage is that, even though there is non-linear feedback, this type of converter tends to be stable. Another advantage is that these converters have very low idle power consumption, which is important for battery-operated equipment. (c) Disadvantage: there is always residual ripple present at the output. Note: A number of students described the basic dc/dc conversion. A gated oscillator regulator is a special case where the oscillator runs at a fixed frequency and duty cycle (no PWM). The gating refers to when the oscillator is turned off completely. To make the scheme work, there has to be some hysteresis (key feature).
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Advanced Circuit Techniques (55:141)
Spring 2012
of a buck-boost converter, assuming the converter is in CCM, and all the components are lossless, is the duty cycle, and is the input voltage. Start by providing schematic showing the essential components (inductor, switch, catch diode, and output capacitor) Next, make a plot of inductor current as a function of time. Write expressions for the change in inductor current during and , where and are the and times Question 4 Derive the expression below for the output voltage
of the switch. Use these expressions to derive the equation. (10 points)
Solution Note: Most people did well on this question. Common mistakes were omitting the figure, not showing where , fits in, and not labeling axes on graphs (what up with this ). The derivation should be such that if you showed it to someone that d oes not know how the converter works, they could follow your reasoning.
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Advanced Circuit Techniques (55:141)
Question 5 Consider the gated-oscillator DC/DC regulator below. The hysteresis for
, , the duty cycle of the 20 kHz oscillator is 70%.
Spring 2012
is 5 mV,
(a) What is the (mean) output voltage for an input voltage of 3 V? (5 points) (b) What is the output ripple voltage? (5 points)
Solution Part (a) The feedback loop stabilizes when the mean voltage at the reference voltage. This is when
node matches the mean
Part (b) Note that the output voltage is ⁄ times the reference voltage. Thus, a hysteresis translates to a 56.6 times larger output ripple. Consequently, the output ripple voltage is . Note: Most students got Part (a) correct, but many had Part (b) wrong.
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Advanced Circuit Techniques (55:141)
Question 6 In the circuit below,
clock frequency
.
Spring 2012
, and and are non-overlapping clocks with
(a) What is the purpose of the circuit? (2 points) (b) What is the 3-dB frequency in Hz? (6 points)
Solution Part (a) This is a high-pass filter. The FETs, the clocks, and
is a SC resistor with value . This
form a high-pass filter. Part (b) ⁄ . The 3-dB frequency of the overall network is resistor along with
⁄
Note: A disappointing number of students got
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wrong…
Advanced Circuit Techniques (55:141)
Spring 2012
Question 7 Explain by using a circuit diagram and a few sentences how one could use two electronic SPDT switches and two capacitors to invert a dc voltage. The switches break before they make, and switch at 20 kHz. (6 points) Solution
When the switches are in the and positions, charges to the input voltage. When the switches change to the and positions, they break before they make. During the break time, holds its charge. When the switches make, they place in parallel with , and confer charge to . Within a few cycles, the voltage across is equal to the input voltage. However, note that the way the switches are wired, the output voltage is inverted.
Note: Most students go this question correct.
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Advanced Circuit Techniques (55:141)
Spring 2012
and a load that draws a constant current . The peak amplitude of the waveform after the bridge rectifier is . Question 8 Consider a full wave rectifier with a smoothing capacitor
(a) Make a neat and detailed sketch the output voltage waveform. Indicate the conduction interval and clearly indicate the ripple voltage . (4 points) (b) Then show that
Here is the frequency of the input to the rectifier, and
is the load current.
(6 points)
You may make reasonable assumptions, but you have to state them. Solution Part (a) Key aspects: rectified full wave,
a straight line, conduction interval, label axes, show , .
Part (b) represents the time the filter capacitor is supplying the load, is as indicated, and is the time the diodes supply the load and replenish the capacitor’s charge (i.e., conduction interva l). Since the
the differential equation for the filter capacitor, namely: becomes for line segment : However, by definition (see figure) so that Further, ⁄, so that load is constant (
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