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Lecture 8 Motors, Actuators, and Power Drives

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Actuators are the means for embedded systems to modify the physical world ... Close-up. Tang/Nguyen/Howe. Layout of electrostatic-combdrive. Ground plate. Folded beams ... – PowerPoint PPT presentation

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Title: Lecture 8 Motors, Actuators, and Power Drives


1
Lecture 8Motors, Actuators, and Power Drives
  • Forrest Brewer

2
Motors, Actuators, Servos
  • Actuators are the means for embedded systems to
    modify the physical world
  • Macroscopic Currents and power levels
  • Thermal Management
  • Power Efficiency (often vs. Performance)
  • Motor Types
  • DC Brush/Brushless
  • AC (shaded pole and induction)
  • Stepper Motors
  • Servo (variety of DC motor)
  • Peisio-electric (Kynar, Canon ultra-sonic)
  • Magnetic Solenoid
  • Electro-static (MEMS)

3
DC Motor Model
  • Torque (force) Current
  • Max Current V/R
  • Max RPM V/Bemf
  • Bemf L dI/dt
  • In generalTorque (V Bemf)/R

4
speed vs. torque, fixed voltage
Linear mechanical power Pm F ? v
Rotational version of Pm t ? w
V
ke
max speed
power output
speed w
speed vs. torque
ktV
stall torque
torque t
R
Jizhong Xiao
5
Controlling speed with voltage
e ke w
  • The back emf depends only on the motor speed.
  • The motors torque depends only on the current,
    I.

t kt I
Istall V/R
V IR e
  • Consider this circuits V

current when motor is stalled
How is V related to w ?
speed 0 torque max
R
e
V
Speed is proportional to voltage.
V
R
w - t
ke
kt ke
DC motor model
Jizhong Xiao
6
Electrostatic MEMS Actuation
  • Electrostatic Drives (MEMS)
  • Basic equations
  • Rotation Drive
  • Comb Drive

7
Electrostatic Actuator Analysis
Plate-1
  • Consider the capacitance of the two figures
  • To good approximation, the capacitance is double
    in the second figure
  • Imagine that the charge is fixed in the top
    figure
  • The stored energy is not the same!
  • The difference must be the work done by the
    motion of the plate

d
V (volts)
Plate-2
Plate-3
Plate-1
d
Plate-2
Plate-3
8
Electrostatic Actuators
Consider parallel plate 1 2
Force of attraction (along y direction)
Fp (½ e V2)(A/g2)
9
Paschen Curve
Breakdown voltage
Ebd100MV/m
Distancepressure (meteratm)
10
Side Drive Motors
Side view of SDM
Top view of SDM
First polysilicon motors were made at UCB (Fan,
Tai, Muller), MIT, ATT Typical starting voltages
were gt100V, operating gt50V
11
A Rotary Electrostatic Micromotor 1?8 Optical
Switch
A Rotary Electrostatic Micromotor 1?8 Optical
Switch A. Yasseen, J. Mitchell, T. Streit, D. A.
Smith, and M. Mehregany Microfabrication
Laboratory Dept. of Electrical Engineering and
Applied Physics Case Western Reserve
University Cleveland, Ohio 44106
Fig. 3 SEM photo of an assembled microswitch with
vertical 200 mm-tall reflective mirror plate.
Fig. 4 Insertion loss and crosstalk measurements
for multi-mode optics at 850 mm.
Micro Electro Mechanical Systems Jan., 1998
Heidelberg, Germany

12
Comb Drives
Tang/Nguyen/Howe
13
Layout of electrostatic-combdrive
Folded beams (movable comb suspension)
Tang, Nguyen, Howe, MEMS89
Stationary comb
Ground plate
Moving comb
Anchors
14
Parallel-Plate Electrostatic Actuator Pull-in
Electrostatic instability
k
m
s0
V
x
x
s0
1/3 s0
V
Vsnap
15
Electrostatic spring
  • Adjustable stiffness (sensitivity) and resonance
    frequency

16
Stepper Motors
  • Overview
  • Operation full and half step
  • Drive Characteristics

17
VR Stepper Motor
M. G. Morrow, P.E.
18
Actual Motor Construction
M. G. Morrow, P.E.
19
Multi-pole Rotation, Full-Step
A S B OFF
M. G. Morrow, P.E.
20
Multi-pole Rotation, Full Step
A OFF B S
M. G. Morrow, P.E.
21
Multi-pole Rotation, Full Step
A N B OFF
M. G. Morrow, P.E.
22
Multi-pole Rotation, Full Step
A OFF B N
M. G. Morrow, P.E.
23
Multi-pole Rotation, Full Step
A S B OFF
M. G. Morrow, P.E.
24
Full-Step Stepping
25
Full-Step, 2-on Stepping
26
Half-stepping
M. G. Morrow, P.E.
27
Unipolar motor
M. G. Morrow, P.E.
28
Bipolar motor
M. G. Morrow, P.E.
29
Torque v.s. Angular Displacement
30
Stepping Dynamics
31
Load Affects the Step Dynamics
32
Drive Affects the Step Dynamics
a
33
Stepper Motor Performance Curves
34
Current Dynamics
35
Drive Circuits
  • Inductive Loads
  • AC Motor Drive (Triac)
  • H-bridge
  • Snubbing and L/nR Stepper Drive
  • PWM
  • Micro-Stepping

36
Inductive Load Drive Circuits
  • BJTs
  • VCEsat 0.4V
  • PD ICVCE
  • MOSFETs
  • VDS ID RDSon
  • PD IDVDS

                     
M. G. Morrow, P.E.
37
Switching Characteristics
VC
VIN
M. G. Morrow, P.E.
38
Switching Characteristics
VC
VIN
M. G. Morrow, P.E.
39
AC Motor Drive
M. G. Morrow, P.E.
40
H-bridge
  • An H-bridge consists of two high-side switches
    (Q1,Q3) and two low-side switches (Q2,Q4)
  • BJTs or FETs

Q1 Q2 Q3 Q4
ON ON Dont use - short circuit
ON ON Dont use - short circuit
OFF OFF Motor off
OFF OFF Motor off
ON OFF OFF ON Forward
OFF ON ON OFF Reverse
ON OFF ON OFF Brake
OFF ON OFF ON Brake
M. G. Morrow, P.E.
41
H-Bridge/Inductor operation
V IR
V V
V 0 (V -IR)
V IR
42
L/nR Drive
43
Current Rise in Detail
44
Performance Improvement with L/nR Drive
45
Pulse-Width Modulation
  • Pulse-width ratio ton/tperiod
  • Never in linear mode
  • Uses motor inductance to smooth out current
  • Saves power!
  • Noise from Tperiod

Benjamin Kuipers
46
Pulse-Code Modulated Signal
  • Some devices are controlled by the length of a
    pulse-code signal.
  • Position servo-motors, for example.

0.7ms
20ms
1.7ms
20ms
Benjamin Kuipers
47
Back EMF Motor Sensing
  • Motor torque is proportional to current.
  • Generator voltage is proportional to velocity.
  • The same physical device can be either a motor or
    a generator.
  • Alternate Drive and Sense (note issue of Coils
    versus Induction)

Benjamin Kuipers
48
Back EMF Motor Control
Benjamin Kuipers
49
Microstepping
  • Use partial Drive to achieve fractional steps
  • Stepper is good approximation to Sine/Cosine
    Drive
  • 2p cycle is 1 full step!
  • Usually PWM to reduce power loss
  • Fractional voltage drop in driver electronics

50
Microstepping Block Diagram
  • Easy to synthesize the PWM from Microcontroller
  • Lookup table interpolation
  • p/2 phase lag table index offset
  • Need to monitor winding current
  • Winding L,R
  • Motor Back EMF
  • PWM Frequency tradeoff
  • Low Freq resonance (singing)
  • High Freq Winding Inductance and switching loss

51
PWM Issues
  • Noise/Fundamental Period
  • Low Freq Singing of motor and resonance
  • High Freq Switching Loss
  • Can we do better?
  • Not unless we add more transitions! (Switching
    Loss)
  • If we bite bullet and use MOS drives can switch
    in 2-50nS
  • Then can choose code to optimize quantitization
    noise vs. switching efficiency
  • Modulated White Noise
  • Sigma-Delta D/A
  • Requires higher performance Controller

52
Motors and Actuators -- Software
  • Embedded motor control is huge, growing
    application area
  • Need drive(sample) rates high enough to support
    quiet, efficient operation
  • Rates roughly inversely proportional to motor
    physical size
  • Stepper Motors are usually micro-stepped to avoid
    humming and step bounce
  • Typical 1kHz rate, 50kHz micro-step slow HP
    motors 300Hz-1kHz
  • Upshot- 1 channel fast or micro-stepped motor
    is substantial fraction of 8-bit processor
    throughput and latency
  • Common to run up to 3 slow motors from single
    uP
  • Common trend to control motor via single, cheap
    uP
  • Control multiple via commands send to control uPs
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