ETC AMC8500

Preliminary Specification
aMC8500
TWO PHASE VARIABLE SPEED
FAN MOTOR CONTROLLER
PRODUCT SPECIFICATION
The aMC8500 is a full featured monolithic brushless DC
motor controller containing all the required functions to
implement fan speed control. This device features a
selectable slope pulse width modulator (PWM) for efficient
speed control with analog and digital control signal
compatibility, programmable minimum speed setting, Hall
amplifier with propriety noise immunity circuitry for proper
drive sequencing, fixed non-overlapping commutation delay
for reduced supply current spiking, dual on-chip 0.5 Ω power
MOSFETs with thermal protection for direct motor drive,
programmable cycle-by-cycle current limiting, internal fault
timer with auto start retry, motor kick start timer to insure start
up, combined frequency generator / rotor lock output,
uncommitted op amp with reference for thermal sensor
voltage scaling, and a selectable automatic low current
power down mode for power sensitive applications.
Pin Configuration
Phase 2
Output
1
16
Phase 1
Output
Current
Limit Set
2
15
Freq Gen.
Rotor Lock
Hall +
3
14
Slope Select
Hall -
4
13
Power
Ground
Reference
Output
5
12
VDD
Minimum
Speed Set
6
11
Signal
Ground
Non-Inverting
Input
7
10
Speed Control
Input
Inverting
Input
8
9
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Analog and digital speed control signal compatibility
Programmable minimum speed setting
Selectable PWM speed control slope
Latching PWM for enhanced noise immunity
Integrated fault timer with auto start retry
Motor kick start timer
Combined frequency generator / rotor lock output
Differential unbuffered and digital Hall compatibility
Hall amplifier with propriety noise immunity circuitry
Pinned out reference
Uncommitted op amp for thermal sensor voltage scaling
Fixed non-overlapping commutation delay
Dual on-chip 0.5 Ω MOSFET motor drives
Programmable cycle-by-cycle current limit protection
Thermal shutdown protection
Under voltage lockout protection
Selectable automatic low current power down mode
Op Amp
Output
Application Diagram
12V
VDD
Ref.
H+
Ø1
H-
Ø2
FG / RL
Output
Reference
Non-Inv.
Inv.
Op
Amp
Output
Commutation
Logic
Motor
Drive
Fault Timer
Applications
•
•
•
•
•
•
•
aMC8500
Personal computer fans
Workstation and mainframe fans
LAN server blowers
Industrial control system fans
Telcom system fans
Instrumentation test and measurement fans
Card rack fans
Minimum
Speed
Speed
Control
PWM
Logic
Slope Select
Current
Limit
Signal Gnd
Current
Limit
Set
Power Gnd
Ordering Information
Part Number
Package
aMC8500DE16
SOIC 16 Lead Exposed Pad
aMC8500QS16
QSOP 16 Lead
Operating Junction
Temperature Range
Marking
-40°C to 125°C
aMC8500
Ayww
Ayww – Assembly site year workweek
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August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Product Description
Preliminary Specification
aMC8500
Absolute Maximum Ratings (Note 1)
Parameter
Power Supply Voltage (Pin 12)
Hall Input Voltage Range (Pin 3, 4)
Speed Control Input Voltage Range (Pin 10)
Rating
Unit
VDD
-0.3 to 18
V
VIR(Hall)
-0.3 to VDD
V
-0.3 to VDD
V
-0.3 to VDD
V
Reference Output Load Current (Pin 5)
IO(Ref)
Internally
Limited
mA
Op Amp Input Voltage Range (Pin 7, 8)
VIR(OA)
-0.3 to VDD
V
Op Amp Output (Pin 9, Note 4)
Voltage Range
Source or Sink Current
VOR(OA)
IO(OA)
-0.3 to VDD
30
V
mA
Slope Select Input Voltage Range (Pin 14)
VIR(LS)
-0.3 to VREF
V
Current Limit Set Input Voltage Range (Pin 2)
VIR(ILim)
-0.3 to VREF
V
VOR(FG/RL)
ISink(FG/RL)
-0.3 to 18
20
V
mA
VD(Ø1/Ø2)
ISink(Ø1/Ø2)
-0.3V to 36
1.5
-1.5
V
A
A
Frequency Generator / Rotor Lock Output (Pin 15)
Voltage Range
Sink Current
Drive Outputs (Pin 1, 16, Note 4)
Voltage Range
Sink Current
Source Current
Thermal Characteristics
SOP-16 Exposed Pad Package
Thermal Resistance, Junction to Air
Thermal Resistance, Junction to Pad
QSOP-16 Package
Thermal Resistance, Junction to Air
ISource(Ø1/Ø2)
°C/W
RØJA
RØJC
92
15
RØJA
136
TJ(max)
-40°C to 125
°C
Storage Temperature Range
Tstg
-60°C to 150
°C
IR Reflow Peak Temperature
Treflow
260
°C
Lead Soldering Temperature (10 sec)
Tlead
300
°C
Electrostatic Discharge (Note 2)
Human Body Model
Machine Model
ESD
Operating Junction Temperature Range
Preliminary Specification – Subject to change without notice
VIR(S)
VIR(MSS)
Minimum Speed Set Input Voltage Range (Pin 6)
Preliminary Specification – Subject to change without notice
Symbol
V
2000
250
Notes:
1. Absolute maximum ratings are limits beyond which operation may cause permanent damage to the device.
These are stress ratings only. Functional operation at or above these limits is not implied.
2. Human Body Model: 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
Machine Model: 200 pF capacitor discharged directly into each pin.
3. These specifications are guaranteed only for the test conditions listed.
4. Maximum package power dissipation limits must be observed.
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August 2006 - 70A04018
Preliminary Specification
aMC8500
Electrical Characteristics
(V D D = 1 2 V, T A = 25°C, unless otherwise noted. Specifications subject to change without notice [Note 3].)
Parameter
Symbol
Min
Typ
Max
Units
Input Threshold Voltage
Pin 14 = Gnd
0% Drive Conduction
100% Drive Conduction
Pin 14 = Open
0% Drive Conduction
100% Drive Conduction
V
Speed Control Input Threshold Voltage for Power Down (IO(ref) ≤1.0 mA)
Input Voltage Below 0% Drive Conduction, Vth(0%), Pin 14 = Gnd
Input Voltage Above 0% Drive Conduction, Vth(0%), Pin 14 = Open
Vth(0%)
Vth (100%)
0.95
2.85
1.0
3.0
1.05
3.15
Vth(0%)
Vth(100%)
2.85
0.95
3.0
1.0
3.15
1.05
Vth(PD)
mV
-
20
20
-
Speed Control Input PWM Signal Transition Time
Maximum allowable rise or fall time for digital control
tr/tf
-
-
50
µs
Input Bias Current, (Vin = 3.5 V)
IIB
-
1.0
-
µA
fPWM
-
30
-
kHz
Modulation Frequency
SLOPE SELECT (Pin 14)
Input Threshold Voltage
Low State
Increasing voltage at Pin 6, 10 causes increase in drive conduction
High State
Increasing voltage at Pin 6, 10 causes decrease in drive conduction
V
VIL(S)
-
-
1.0
VIH(S)
2.8
-
-
II(S)
-
10
-
µA
Input Differential Voltage Sensitivity
Required signal level to enable drive commutation
VID(Hall)
-
20
40
mVpp
Input Hysteresis Voltage (Vin = 3.5 V)
VIH(Hall)
-
10
-
mV
Input Resistance
RIN(Hall)
-
-
MΩ
Input Common Mode Voltage Range
VICM(Hall)
0 to
VDD
3.0
-0.3
to
VDD
+0.3
-
V
Input Offset Voltage (Vin = 3.5V)
VIO
-
2.0
-
mV
Input Bias Current (Vin = Gnd)
IIB
-
-
nA
VICM(OA)
-
50
0 to
4.2
-
V
Open Loop Voltage Gain
AVOL
80
100
-
dB
Gain Bandwidth Product (f = 10 kHz)
GBW
-
70
-
kHz
Output Voltage Swing
High State (Isource = 5.0 mA to Gnd)
Low State (Isink = 5.0 mA to VDD)
VOH(OA)
VOL(OA)
-
VDD
-1.5
0.5
-
Low State Input Pull-Up Current (VIL(S) = 0 V)
HALL AMPLIFIER (Pin 3, 4)
OP AMP (Pin 7, 8, 9)
Input Common Mode Voltage Range
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V
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
SPEED CONTROL (Pin 10) and MINIMUM SPEED SET (Pin 6)
Preliminary Specification
aMC8500
REFERENCE (Pin 5)
Output Voltage (IO = 5.0 mA)
Vref
3.325
3.5
3.675
V
Line Regulation (VDD = 6.0 V to 15 V, IO = 5.0 mA)
Refline
-
2.0
30
mV
Load Regulation (VDD = 6.0 V, IO = 1.0 mA to 10 mA)
Refload
-
11
30
mV
ISC
-
50
-
mA
Reference Output Load Current For Automatic Power Down Feature
(Pin 10 = 500 mV, Pin 14 = Gnd, t > 2.0s)
(Pin 10 = 3.5 V, Pin 14 = Open, t > 2.0s)
Enabled
Disabled
IO(PD)
mA
2.0
1.4
1.6
1.0
-
FAULT TIMER
Drive Enabled Time During A Fault Condition
ton(Flt)
-
0.25
-
s
Drive Disabled Time Before Restart
toff(Flt)
-
2.0
-
s
ton(KS)
-
1.0
-
s
KICK START TIMER
Motor Kick Start Time (100% duty cycle applied)
FREQUENCY GENERATOR / ROTOR LOCK (Pin 15)
Low State Output Sink Voltage (Isink = 1.0 mA)
VOL(FG/RL)
-
0.13
0.25
V
Off-State Leakage Current (Voff = 12 V)
Ioff(Tach)
-
0.1
1.0
µA
Minimum Hall Frequency For Rotor Lock Output High State
fRL(min)
-
4.0
-
Hz
Low State Output Voltage (Isink = 500 mA)
VOL(Drv)
-
250
300
mV
Off-State Leakage Current (Voff = 30 V)
Ioff(Drv)
-
-
5.0
µA
MOTOR DRIVES (Pin 1, 16)
Current Limit Threshold (Pin 2 open, Note 4)
Non-Overlapping Commutation Delay
ILim
900
1100
1300
mA
tdly(Com)
-
40
-
µs
Vth(on)
VH
-
4.7
500
-
V
mV
IS
IS(PwrDn)
-
1.6
130
2.0
200
mA
µA
TOTAL DEVICE (Pin 12)
Power Supply Threshold Voltage
Start-Up (VDD increasing)
Hysteresis (VDD decreasing after turn-on)
Power Supply Current
Operating
Power Down (Pin 10 = 0.5 V, IO(ref) ≤1.0 mA, t > 2.0s, Pin 14 = Gnd)
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August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Short Circuit Current (Note 4)
100
Kick Start
1.0 sec.
VDD = 12 V
Pin 14 = Gnd
TA = 25°C
80
Motor remains at min
speed setting. Auto
power down disabled.
IO(Ref) ≥2.0 mA
60
Minimum speed set shown
for 1.5 V, 1.7 V, and 1.9 V.
40
Motor turns on/off at min
speed setting. Auto power
down enabled after 1 sec.
IO(Ref) ≤1.0 mA
20
0
0
1.0
2.0
3.0
4.0
Vin(SC), Speed Control Input Voltage (V)
5.0
%ton, Motor Drives Percent On-Time (%)
%ton, Motor Drives Percent On-Time (%)
Figure 1- Motor Drives Percent On-Time
versus Speed Control Input Voltage
100
VO, Output Voltage (V)
1.95
60
40
20
0
0
VO(OA), Output Voltage (V)
Motor turns on/off at
min speed setting.
Auto power down
enabled after 1.0 sec.
IO(Ref) ≤1.0 mA
Minimum speed set shown
for 2.1 V, 2.3 V, and 2.5 V.
1.0
2.0
3.0
4.0
Vin(SC), Speed Control Input Voltage (V)
2.0
1.5
Figure 5- Op Amp Source and Sink
Output Voltage versus Current
Figure 6- Frequency Generator / Rotor Lock
Low State Output Voltage versus Sink Current
VDD
-1.0
VDD = 12 V
TA = 25°C
-2.0
2.0
Low state output
Load to VDD
1.0
Gnd
4.0
8.0
12
IO, Output Load Current (mA)
© Andigilog, Inc. 2006
5.0
VDD = 12 V
AV = +1.0
RL = 10 M
CL = 10 pF
TA = 25°C
2.5
4.0 μs/Division
High state output
Load to ground
0
Motor remains at min
speed setting. Auto
power down disabled.
IO(Ref) ≥2.0 mA
VDD = 12 V
Pin 14 = Open
TA = 25°C
1.0 μs/Division
16
VOL(FG/RL), Low State Output Voltage (V)
VO, Output Voltage (V)
2.0
0
Kick Start
1.0 sec.
Figure 4- Op Amp
Large Signal Transient Response
VDD = 12 V
AV = +1.0
RL = 10 M
CL = 10 pF
TA = 25°C
0
Figure 2- Motor Drives Percent On-Time
versus Speed Control Input Voltage
80
Figure 3- Op Amp
Small Signal Transient Response
2.05
aMC8500
1.0
VDD = 12 V
TA = 25°C
0.8
0.6
0.4
0.2
0
0
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1.5
3.0
4.5
Isink, Sink Current (mA)
6.0
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Preliminary Specification
VDD = 12 V
TA = 25°C
-8.0
-16
-24
-32
0
0.6
VOL(Drv), Low State Voltage (V)
Vref, Reference Output Voltage (V)
0
4.0
8.0
12
16
IO, Reference Output Source Current (mA)
20
VDD = 12 V
TA = 25°C
0.5
0.4
0.3
0.2
0.1
0
0
0.2
0.4
0.6
0.8
Isink, Sink Current (A)
1.0
1.2
VDD = 12 V
CPin 2 = 10 nF
TA = 25°C
0.8
0.6
0.4
0.2
0
0
0.2
0.4
0.6
0.8
Vpgm, Programming Voltage, Pin 2 (V)
© Andigilog, Inc. 2006
1.0
Figure 8- Reference Output Voltage
versus Power Supply Voltage
TA = 25°C
3.0
2.0
1.0
0
0
1.0
4.0
8.0
12
VDD, Power Supply Voltage (V)
16
Figure 10- Phase 1 / Phase 2 Drive Output
On Resistance versus Power Supply Voltage
ISink = 500 mA
TA = 25°C
0.9
0.8
0.7
0.6
0.5
0.4
4.0
1.2
Ilim, Current Limit Threshold (A)
Ilim, Current Limit Threshold (A)
Figure 11- Phase 1 / Phase 2 Current Limit Threshold
versus Programming Voltage
1.2
1.0
4.0
Figure 9- Phase 1 / Phase 2 Drive Output
Low State Voltage versus Sink Current
Ron, Drive Output On Resistance (Ω)
ΔVref, Reference Output Voltage Change (mV)
Figure 7- Reference Output Voltage Change
versus Output Source Current
aMC8500
1.0
6.0
8.0
10
12
14
VDD, Power Supply Voltage (V)
16
18
Figure 12- Programming Resistance
versus Current Limit Threshold
VDD = 12 V
CPin 2 = 10 nF
TA = 25°C
0.8
0.6
0.4
0.2
0
10 k
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100 k
1.0 M
Rpgm, Programming Resistance (Ω)
10 M
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Preliminary Specification
Preliminary Specification
aMC8500
Figure 13- Representative Block Diagram
12 V
H
S
VDD
Non-Inverting
Input
Inverting
Input
Reference
5
Hall Input 4
Phase 1
Output
16
Under Voltage
Lockout
Phase 2
Output
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Op Amp
1
Frequency
Generator /
Rotor Lock
Output
7
Fault Timer
Power Down
Kick Start
8
Output
Thermal
Shutdown
15
9
Minimum
Speed Set
Input
6
Oscillator
PWM
Comparator
R
Speed Control
Input
Q
2
S
Current Limit
Comparator
Digital
Detector
Signal Ground
Power
Ground
R
PWM
Logic
10
13
Current
Limit
Latch
Min Speed
Comparator
Current
Limit
Set
10 μA
11
14
Slope Select
INTRODUCTION
The aMC8500 is a full featured two phase half wave variable speed brushless motor controller containing all the required
functions for implementing a fan control system. Motor control features consists of a selectable slope pulse width modulator
(PWM) with double pulse suppression for efficient speed control that is compatible with an analog voltage or a varying duty
cycle digital pulse train, a programmable minimum speed set input, and an uncommitted op amp with a pinned out reference
for speed control signal scaling, Hall sensor amplifier with propriety noise immunity circuitry for proper drive sequencing,
non-overlapping commutation drive for reduced supply current spiking, on-chip 0.5 Ω power MOSFETs for direct coil drive.
Protective and diagnostic features include an internal fault timer with auto start retry, motor kick start timer to insure proper
start up, programmable cycle-by-cycle current limiting, power supply under voltage lockout, and over temperature thermal
shutdown, and a combined frequency generator / rotor lock output for status reporting. Also included is a selectable
automatic low current power down mode aimed at power sensitive applications.
The aMC8500 is designed for use in thermal open or closed loop systems. It can be controlled by simple NTC or PTC
thermistors, Simistor™ silicon temperature sensors, or by complex digital or microcontroller based temperature monitors.
FUNCTIONAL DESCRIPTION
A representative block diagram is shown in Figure 13 and a detailed discussion on each of the functional blocks and
features are given in the following sections. A complete list of the pin functions with a brief description is shown in Figure 33.
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Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Reference
Output
Hall +
Input 3
12
N
MS
N
aMC8500
Speed Control
Motor speed is efficiently controlled with the use of pulse width modulation, PWM. The voltage applied to the Speed
Control Input, Pin 10, provides control of motor speed by varying the drive percent on-time or conduction time of the Phase 1
and Phase 2 outputs during the commutation cycle. The control signal can be in the form of an analog voltage ranging from
1.0 V to 3.0 V, or a variable duty cycle digital pulse train having a low state maximum of 0.98 V, a high state minimum of
3.02 V, with maximum transition times 50 µs. The control signal to PWM transfer slope or Speed Control Input voltage to
drive percent on-time, is controlled by the Slope Select input, Pin 14. When connected to ground, an increase in control
voltage or a digital high state results in an increase in drive output on-time. When unconnected, an increase in control
voltage or a digital high state results in a decrease in drive output on-time.
A Minimum Speed Set Input is made available at Pin 6 and it has a control transfer and slope that is identical to that of
Pin 10. It is designed to be programmed form an analog voltage that ranges from 1.0 V to 3.0 V, which can be derived from
the Reference. The minimum speed programmed at this input will take control of the motor speed if it is greater than the
speed being requested at the Speed Control input. When directly controlling motor speed from a variable duty cycle digital
pulse train, the minimum speed set feature is not available and the comparator input must be disabled. A method for
preserving this feature is shown in Figure 40.
Figure 1 shows the Motor Drives percent on-time versus the Speed Control input voltage with Pin 14 connected to ground
for positive slope control. Notice that there are two defined outcomes when the Speed Control input voltage falls below that
of the Minimum Speed Set. The first is that the motor continuously runs at the programmed minimum speed setting and this
is selected by loading the Reference with 2.0 mA or more to disable auto Power Down. The second outcome is that the
motor turns off after 1.0 second and this is selected by loading the Reference with 1.0 mA or less to enable auto Power
Down. This gives the fan designer a choice between letting the motor run at a minimum speed or to stop running when
Speed Control falls below the programmed minimum speed setting.
Figure 2 shows the Motor Drives percent on-time versus the Speed Control input voltage with Pin 14 unconnected for
negative slope control. The minimum speed operating characteristics are selected in the same manner as above but with the
defined outcomes now occurring when the Speed Control input voltage rises above that of the Minimum Speed Set. The
speed control and minimum speed operations are shown in table form in Figure 14. Compatibility with both analog and digital
control signals combined with the ability to select both the transfer slope and automatic power down, allows this device to
interface into a vast array applications.
Figure 14- Speed Control and Minimum Speed Set Operation
Speed Control Input
Pin 10
Signal
(V)
0 to 1.0
>1.0 to <3.0
3.0 to 5.0
Voltage
Positive
Pulse
Negative
Pulse
Controlling
Input
Gnd
(Disabled)
Speed
Control
Minimum
Speed Set
0 to <1.7
>1.7 to 3.0
1.7
>3.0 to 5.0
Pulse
<0.98 to >3.02
Gnd
(Disabled)
Speed
Control
Tied to Pin 14
(Disabled)
Speed
Control
5.0 to 3.0
<3.0 to >1.0
1.0 to 0
Voltage
Minimum
Speed Set
Input
Pin 6
(V)
<2.3 to 1.0
2.3
<1.0 to 0
Pulse
>3.02 to <0.98
Tied to Pin 14
(Disabled)
Speed
Control
Speed
Control
Motor
Drive
(% Low)
0
0 to 100
Gnd
Speed
Control
Minimum
Speed Set
3.0 to >2.3
Slope
Select
Pin 14
Zero speed, power down mode if IO(ref) ≤1.0 mA, t > 1.0s.
%ton = (VSC - 1.0) / 0.02
100
Maximum speed.
35
Speed control voltage is less than minimum speed set.
35 to
100
100
Duty
Cycle
0
0 to 100
100
Open
Comments
35
35 to
100
100
Duty
Cycle
Speed control voltage is greater than minimum speed set.
Maximum speed.
Positive pulse width duty cycle controlled from Pin 10.
Zero speed, power down mode if IO(ref) ≤1.0 mA, t > 1.0s.
%ton = 100 - (VSC - 1.0 / 0.02)
Maximum speed.
Speed control voltage is greater than minimum speed set.
Speed control voltage is less than minimum speed set.
Maximum speed.
Negative pulse width duty cycle controlled from Pin 10.
Note that if the end application does not require a programmed minimum speed or is to be controlled by a variable duty
cycle digital pulse train, the Minimum Speed Set comparator must be disabled as shown in Figure 28. For applications that
do not require speed control, the device can be configured to provide commutation only, yielding maximum motor speed
without requiring any additional components. This is accomplished by directly grounding Pins 6 and 10, while leaving Pin 14
open.
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August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Preliminary Specification
Preliminary Specification
aMC8500
Commutation
The aMC8500 features a non-overlapping commutation delay circuit that prevents simultaneous drive conduction for
reduced power supply current spikes and radio frequency interference (RFI). The non-overlap delay time (tdly) is internally set
to 40 µs. The commutation waveforms and truth table are shown below in Figures 15 and 16.
Figure 15- Two Phase, Two Step, Half Wave Commutation Waveforms
0
Hall
Inputs
180
360
Rotor Electrical Position (Degrees)
540
720
0
180
360
540
720
H+
HVClamp
Phase 1
Drain
Voltage VMotor
0
Phase 1
Drain
Current
0
tdly(Com)
tdly(Com)
VClamp
Phase 2
Drain
Voltage VMotor
0
Phase 2
Drain
Current
FGRL
Output
Voltage
0
0
Full Speed (100% PWM)
Reduced Speed (≈ 50% PWM)
Figure 16- Commutation Truth Table
Hall Inputs
+
(Pin 3)
(Pin 4)
Low
High
X = Don’t care
© Andigilog, Inc. 2006
System
Fault
None
Drive Outputs
Phase 1
Phase 2
(Pin 16)
(Pin 1)
Off
Low
FGRL
Output
(Pin 15)
Low
High
Low
None
Low
Off
High
X
X
Yes
Off
Off
High
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Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Hall Inputs
Rotor position is detected by a single Hall sensor to enable proper motor drive commutation. The H+ and H- Amplifier
inputs are designed to interface with a wide variety of economical 4 pin unbuffered 'naked' or 3 pin buffered 'digital' Hall
sensor types. The unbuffered sensors provide a low level differential output signal that is directly proportional to the rotors
applied magnetic field. The sensor outputs connect directly to the H+ and H- inputs. The Amplifier has a differential input
sensitivity of 20 mV with a common mode voltage range that extends from VDD to ground. By extending the input range to
include ground, the need for offsetting the Hall output voltage with a series ground resistor is eliminated. Figures 20 through
22 show three methods of biasing unbuffered Hall sensors. The aMC8500 Hall Amplifier features enhanced noise rejection
by combining a small level of input hysteresis with a propriety zero crossing detector and a timed lockout.
The buffered Hall sensors provide a high level digital output signal that changes state in direct response the rotor magnetic
pole transitions. This output signal is single ended and can be applied to either the H+ or H- input while biasing the unused
input to a level that is within the output voltage swing of the sensors. Economical buffered Hall sensors typically contain an
NPN open collector sink only output which requires a pull-up resistor. Figures 23 and 24 show two methods for biasing
buffered Hall sensors.
Preliminary Specification
aMC8500
Op Amp
A fully compensated Op Amp with access to both inputs and output is provided to facilitate thermal sensor voltage scaling.
The amplifier features a wide input common mode voltage range that extends from ground to 4.2 V, a DC voltage gain of
100 dB, and a 70 kHz gain bandwidth product. The amplifier output exhibits an voltage swing that extends from ground to
VDD - 1.7 V, is capable of sinking and sourcing up to 10 mA, and is unity gain stability when driving capacitive loads. In
applications where a single amplifier input can exceed the upper level of the common mode voltage range, the output will
always maintain the proper state. If both inputs exceed the upper level of the common mode voltage range, a low state
output phase reversal can occur and although non destructive, it may result in unexpected system behavior.
If the intended application does not require use of the Op Amp, the inputs must be connected to a fixed low impedance
source in a manner that will force the output into a defined state. This will prevent the possibility of amplifying unwanted
noise which can result in erratic circuit behavior. Figure 27 shows three suggested connection methods.
Frequency Generator / Rotor Lock
Motor speed and fault signals are provided by the Frequency Generator and Rotor Lock output at Pin 15. These signals
can provide diagnostic information to a thermal system controller. During normal operation, the output provides a digital
square wave that switches at the Hall sensor commutation frequency. Internally, this signal is used to continuously reset the
Fault Timer. If the motor encounters an obstruction, the decrease in rotational speed will result in a corresponding increase
in time between reset pulses. If this time exceeds 0.25 s (ton(Flt)) a fault will be detected, which in turn will terminate motor
drive and place Pin 15 into a high state, thus indicating a rotor lock condition. After an off time cool down period of 2.0 s
(toff(Flt)) has elapsed, the Fault Timer circuit will apply maximum drive in attempt to restart the motor for another 0.25 s. This
on/off cycling will repeat indefinitely until the motor restarts, or is commanded to stop by the Speed Control and Minimum
Speed Set inputs. Upon a successful restart, Pin 15 will resume switching at the Hall commutation rate after completion of
the Kick Start interval.
The Frequency Generator and Rotor Lock output consists of an N-channel open drain device and therefore requires an
external pull-up resistor. An internal high gain buffer with hysteresis is used to insure that the output waveform is always
rectangular even when the peak to peak Hall output signals are at a low level. The operating waveforms are shown in
Figure 17.
Figure 17- Frequency Generator / Rotor Lock Waveforms
Differential
Hall Inputs
Possible Low Or High State
Rotor Locked
Fault
Detected
0.25 s
Fault Timer
Motor Drives
Rotor Free
ton(Flt) 0.25 s
toff(Flt) 2.0 s
On
Off
On
Off
On
Running
Cool Down
Retry
Cool Down
Running
Frequency
Generator /
Rotor Lock
Output
Defaults To High State After Fault Detected
Constant Speed
© Andigilog, Inc. 2006
Rotor Locked or Rotating Below
Minimum Hall Frequency
- 10 www.andigilog.com
Kick
Start
1.0 s
Accelerating
Constant Speed
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Reference
A pinned out 3.5 V Reference with a tolerance ±5.0% is made available to ease the implementation of motor control and
allow additional system features. The Reference can be used to program the minimum speed set input, provide Hall sensor
power, or thermal sensor voltage scaling when used in conjunction with the uncommitted Op Amp. The Reference output
also provides a means to selectively enable or disable the device's automatic low current power down feature. Automatic
power down is enabled if the output load current is 1.0 mA or less, and disabled if it is 2.0 mA or greater. The Reference is a
source only output and therefore is not designed to sink current from a higher voltage source. It is capable of sourcing in
excess of 10 mA over temperature and has short circuit protection. In applications that require additional current capability,
the output can be buffered with the addition of an external PNP transistor as shown in Figure 25. This simple circuit has the
advantage of moving any additional regulator power dissipation off chip but it does not maintain output short circuit
protection.
Preliminary Specification
aMC8500
%Smax, Percent Maximum Motor Speed (%)
Figure 18- Typical DC Motor Startup and Run Characteristics
Kick Start 100% Voltage
1.0 Second
100
80
Kick Start Extended
Speed Range
60
40
Minimum Startup Speed
35% On-Time
20
0
Typical Useful Speed Range
Minimum Run Speed
10% On-Time
0
20
40
60
80
%ton, Motor Drives Percent On-Time (%)
100
The Kick Start time, ton(KS), is internally set to 1.0 second and is automatically activated whenever the motor is at rest and
commanded to run, or when it is under a command to run and one of the following events takes place:
1) Device comes out of power down mode
2) Rotor was locked and the obstruction has cleared
3) Device recovered from a thermal shutdown
4) Device comes out of an under voltage lockout condition
Current Limit
Abnormally high drive current conditions can occur if the motor is mechanically overloaded and may result in device and
the drive coil overheating. During motor overload, any reduction in rotational speed reduces the generated back
electromotive force, EMF, resulting in an corresponding increase in drive current. The most severe condition occurs when
the rotor is locked and there is no back EMF generated. Under this condition, the drive current is limited only by the
resistance total of the MOSFET switch and the driven coil. In order to protect the device and motor from abnormally high
currents, a programmable Current Limit Comparator is incorporated. The comparator indirectly senses the drive current and
when a maximum level is exceeded, the motor drive on-time is immediately terminated on a cycle-by-cycle basis of either the
internal oscillator or the digital control signal applied to the Speed Control Input.
The current limit threshold defaults to a peak current of 1.1 A with Pin 2 open. This level can be reduced by either applying
a bias voltage to Pin 2 or by connecting a single resistor from this pin to ground. Figures 11 and 12 show the current limit
behavior while Figure 32 illustrates two biasing methods. The Current Limit Set input is high impedance and in most
applications will require a 10 nF bypass capacitor to prevent false triggering due to noise pick up.
© Andigilog, Inc. 2006
- 11 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Kick Start
Most DC motors exhibit a large difference between the voltage required to insure startup and minimum speed operation.
Figure 18 shows this difference as a hysteretic characteristic and is dependent upon bearing friction, lubrication,
temperature, and rotor inertia. With the majority of motor controllers presently available, the applied voltage for minimum
speed operation must be set equal to or greater than that required for startup. This limits the motors useful speed range from
about 35 to 100 percent even though most motors will operate down to 10 percent. In order to guarantee near minimum run
speed operation, the mechanical startup hysteresis must be overcome. This is accomplished in the aMC8500 by kick starting
the motor in a controlled manner where full power is initially applied for a for a prescribed time, and control then reverts back
to the level that is dictated by either the Speed Control or Minimum Speed Set input. This is graphically shown in Figures 1
and 2. With reliable starting guaranteed, the useful speed range is increased by approximately 25%, yielding lower speed
operation for reduced acoustic noise and extended motor life.
aMC8500
Motor Drives
The aMC8500 contains two 0.5 Ω N-channel power MOSFETs that are designed to directly drive the motor coils from the
Phase 1 and Phase 2 outputs. The drive characteristics are shown in Figures 9 and 10. Each output contains a 36 V zener
with a series diode that connects from the drain to the gate. This configuration provides active clamp protection for the
MOSFETs when switching off the inductive motor load. In applications that demand driving higher current or higher voltage
motors, external MOSFET power transistors can be used. Two examples are shown in Figures 29 and 30. Although this
device is designed to drive two phase half wave motors, a method for driving single phase full wave motors is shown in
Figure 31.
Due to the inherent winding coupling that is present in two phase motors, the drain voltage of the off phase will be driven
negative and current will be sourced from that output. This current will cause additional device heating and may affect
operation of high current motors at elevated ambient temperatures. A simple solution is to place the cathode of a low forward
drop Schottky diode from each drive output to ground. Likewise if the motor windings are highly inductive, the internal active
clamp will be required to dissipate this energy which will also result in additional heating. This too can be eliminated with the
addition of an external zener diode connected from each drain to ground. The zener breakdown voltage should be in the
range of 30 V to 34 V.
Under Voltage Lockout and Auto Power Down
An Under Voltage Lockout circuit has been incorporated to prevent erratic device operation under low power supply
conditions. This circuit enables the Motor Drives when VDD rises above 4.7 V to guarantee full IC functionality, and disables
the drives when VDD falls below 4.2 V. The UVLO circuit has 500 mV of hysteresis to prevent oscillations as the thresholds
are crossed during power-up and power-down. The IC is designed to directly drive 9.0 V and 12 V motors.
As previously discussed, the device features a selectable auto Power Down mode. This mode is automatically entered
when the voltage applied to the Speed Control Input commands zero or less than zero percent on-time. When entered, the
power supply current is reduced from 1.6 mA to 130 μA. Refer to Figures 1, 2, and 14.
Thermal Shutdown
Internal Thermal Shutdown circuitry is provided to protect the device in the event that the maximum junction temperature is
exceeded. When activated, typically at 140°C, the Motor Drive outputs are disabled to reduce device power dissipation. This
feature is intended to prevent catastrophic device failures in the event of accidental overheating. Although it is possible to
operate the device above the specified maximum junction temperature of 125°C, this protection feature is not intended to be
used as a substitute for proper thermal system design. When the junction temperature falls below 120°C, normal device
operation resumes. Refer to Figure 19.
Figure 19- Thermal Shutdown Operation
Thermal
Shut Down
Deactivated
Thermal
Shut Down
Activated
Motor
Drives
Enabled
Motor
Drives
Disabled
TJ(max)
80
100
120
140
TJ, Junction Temperature (°C)
160
SYSTEM APPLICATIONS
The following section shows numerous device circuit configurations and several complete fan control solutions with a brief
description. For clarity, many of the circuits show only the internal functional blocks that are of interest with the associated
pin numbers.
© Andigilog, Inc. 2006
- 12 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Preliminary Specification
Preliminary Specification
Figure 20- Motor Supply Powered Unbuffered Hall
aMC8500
Figure 21- Reference Powered Unbuffered Hall
VM
VM
Asahi Kasei
HW-101A
R1
H
H
VDD
12
3
12
VDD
4
Under Voltage
Lockout
5
3
4
Under Voltage
Lockout
Reference
Hall Amplifier
Non-Overlap
Commutation
Hall Amplifier
Non-Overlap
Commutation
When powering an unbuffered Hall sensor from motor voltage VM,
resistor R1 is required. This resistor sets the Hall operating current
and places the output within the input common mode voltage range
of the Hall Amplifier.
Unbuffered Hall sensors that require less than 10 mA can be
powered directly from the Reference output thus eliminating the
need for bias resistor R1. This bias method will disable the
automatic power down feature if the sensors require more than
2.0 mA.
Figure 22- Op Amp Powered Unbuffered Hall
Figure 23- Motor Supply Biased Buffered Hall
VM
VM
H
12
VDD
5
Reference
3
4
R2
Toshiba
TSH124
VDD
Hall Amplifier
Non-Overlap
Commutation
Op Amp
H
R3
Under Voltage
Lockout
7
R1
12
3
4
Ana Chip
ATS177
Under Voltage
Lockout
Hall Amplifier
Non-Overlap
Commutation
8
9
The Op Amp output can be used as alternative method for powering
unbuffered Hall sensors that require less than 10 mA. This method
eliminates the need for bias resistor R1 while also preserving the
automatic power down feature. With this bias method the reference
output is essentially unloaded.
Pull-up resistor R1 is required when using buffered Hall sensors that
have an open collector output. Resistors R2 and R3 bias the unused
amplifier input to a level that is within its input common mode range.
Figure 24- Reference Biased Buffered Hall
Figure 25- Reference Buffer
VM
VM
R1
H
VDD
12
3
4
KEC
KTA1270
Ana Chip
ATS177
0.1
5
Reference
Under Voltage
Lockout
5
Hall Amplifier
Non-Overlap
Commutation
VDD
Reference
12
Under Voltage
Lockout
Load
Resistor R1 is required for buffered Hall sensors with an open
collector output. Resistors R2 and R3 can be eliminated by biasing
the unused amplifier input from the reference.
© Andigilog, Inc. 2006
100
With the addition of an economical PNP transistor, the Reference
output current can be boosted above 100 mA. This simple buffer
circuit will not have the benefit of maintaining short circuit protection.
- 13 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Toshiba
TSH124
Preliminary Specification
aMC8500
Figure 26- Higher Voltage Reference
5
3.5 V
Reference
7
8
R1
R2
R2
VO = VRef
Op Amp
R1
+1
VO Max = VDD - 1.7 V
9
The Op Amp can be used to gain up the Reference voltage in applications that require an additional regulated voltage source. This circuit
can supply up to 10 mA for powering additional circuitry or to provide a higher reference voltage. To insure that the Op Amp output
maintains regulation, the maximum programmed output voltage must be less than VDD - 1.7 V.
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
VO
Figure 27- Connections If Op Amp Is Not Required
5
5
Reference
7
7
Op Amp
5
Reference
7
Op Amp
8
8
8
9
9
9
Unity gain amplifier configuration with
the output forced low.
Reference
Comparator configuration with the
output forced high.
Op Amp
Comparator configuration with the
output forced low.
Figure 28- Connections To Disable Minimum Speed Set Or Digital Signal Speed Control Operation
Slope Select Grounded
5
7
Slope Select Open
Reference
5
Op Amp
7
8
Op Amp
8
9
6
Reference
9
Oscillator
R
Min Speed
Comp
PWM Comp
6
R
PWM
Logic
1
Min Speed
Comp
PWM Comp
PWM
Logic
1
Digital
Detector
10
μA
11
Oscillator
14
Digital
Detector
10
μA
11
14
If the end application does not require a programmed minimum speed or is to be controlled by a variable duty cycle digital pulse train, the
Minimum Speed Set comparator must be disabled by connecting Pin 6 directly to Pin 14.
© Andigilog, Inc. 2006
- 14 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification
aMC8500
Figure 29- Driving Higher Current Motors
12 V
H
S
12
3
4
N
M
S
16
Under Voltage
Lockout
1
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
The Current Limit Comparator protects the Motor Drives by limiting the output sink current to 1100 mA. In applications that require driving
higher current motors, the drive current can be significantly increased with the addition of two external P-channel MOSFET. Current limit
protection is not maintained since the load is no longer in series with the internal MOSFETs.
Figure 30- Driving Higher Voltage Motors
48 V
12 V
H
12
3
4
S
N
M
N
S
16
Under Voltage
Lockout
Hall Amplifier
Non-Overlap
Commutation
1
Motor
Drives
The Motor Drives are limited to a maximum of 36 V. These outputs can be cascoded with two external N-channel MOSFETs for driving
higher voltage motors. The cascode configuration maintains current limit protection since the load is in series with the internal MOSFETs.
© Andigilog, Inc. 2006
- 15 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
N
Preliminary Specification
aMC8500
Figure 31- Driving Single Phase Full Wave Motors
12 V
H
10
k
0.1
S
N
M
N
S
10
k
12
3
10 k
4
16
Under Voltage
Lockout
1
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Single phase full wave motors can be driven with the addition of two external P-channel MOSFETs. With the gates cross coupled as
shown above, the internal and external MOSFETs can perform as a full bridge driver. Commutation shoot through current is minimized by
the internal non-overlapping delay circuit. The resistor capacitor time constant must be just long enough to prevent pulse width modulation
of the two external PFETs. Current limit protection is maintained since the load is in series with the internal MOSFETs. The motor drive
outputs are limited to a maximum of 36 V.
Figure 32- Current Limit Threshold Programming, Noise Pick Up and Motor Soft Acceleration
Current
Limit
Latch
13
R
Q
10 μA
S
Current Limit
Comparator
Current
Limit
Set
2
Noise
Pick Up
Elimination
Current Limit
Threshold Reduction
To Vref
Soft Motor
Acceleration
To VM
Optional
10 nF
Caccl
110 k
Bypass
Capacitor
Single Resistor
Current Source
Biased
Dual Resistor
Reference
Biased
The Current Limit Set input is susceptible to noise pick up and in most applications will require a 10 nF bypass capacitor. The Current
Limit Comparator threshold can be reduced by connecting a single resistor from Pin 2 to ground. This is the most economical
programming method but it is somewhat less accurate than using the dual resistor method shown. This is due to the fact that the
Reference Output is more accurate than the absolute values of the internal current source pull-up and terminating resistor. Motor soft
acceleration during power-up can be accomplished by connecting a capacitor from Pin 2 to ground. During initial device power-up, the
internal current source will charge capacitor Caccl thus gradually increasing the current limit threshold. The diode shown is optional and
may not be required if there is sufficient time for the internal components to discharge the capacitor from when the power source is
removed and then reapplied.
© Andigilog, Inc. 2006
- 16 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
10 k
0.1
Preliminary Specification
aMC8500
Figure 33- Pin Function Description
Function
1
Phase 2 Output
2
Current Limit Set
3
4
Hall +
Hall -
5
Reference Output
6
Minimum Speed
Set
7
Non-Inverting Input
8
Inverting Input
9
Op Amp Output
10
Speed Control
Input
11
Signal Gnd
12
13
VDD
Power Ground
14
Slope Select
15
Freq. Generator /
Rotor Lock
16
Phase 1 Output
Description
This output directly drives phase 2 of a unipolar motor. It is active low when the voltage applied to the Hall input exceeds that of Hall +.
This input is left unconnected for a maximum motor drive current sink current of 1100 mA. The sink current
can be programmed to a lower level by connecting a resistor from this input to ground. Most applications will
require a 10 nF bypass capacitor on this pin to prevent noise pick up.
This input connects to the output of an unbuffered differential type Hall sensor.
This input connects to the output of an unbuffered differential type Hall sensor.
This is the reference output and is capable of sourcing in excess of 10 mA. It is also used to selectively
enable or disable the automatic power down feature. Automatic power down is enabled if the reference load
current is 1.0 mA or less, and disabled if it is 2.0 mA or more.
This input is used in conjunction with the Reference Output to program the minimum motor speed or the
threshold for automatic power down. If continuous minimum speed operation is desired, the automatic power
down feature must be disabled. The minimum speed set feature is not available when controlling motor
speed from a variable duty cycle digital pulse train and this input must be disabled by connected it to Pin 14.
This is the non-inverting input of the Op Amp. It has an operating voltage range that extends from ground to
4.2 V.
This is the inverting input of the Op Amp. It has an operating voltage range that extends from ground to
4.2 V.
This is the Op Amp output and it is capable of sinking or sourcing up to of 10 mA. The Op Amp can be used
in conjunction with the Reference for scaling a speed control signal derived from a temperature sensor.
A voltage level that ranges from 1.0 V to 3.0 V or a variable duty cycle pulse is applied to this input for
controlling the motor speed. A positive or negative speed control slope can be selected via Pin 14.
This pin is the ground return for the control circuitry. It connects directly to the power source ground terminal.
Internally this pin connects to the device substrate and the exposed thermal pad.
This pin is the control circuit positive supply. It connects to the power source positive terminal.
This pin is the ground return for the motor drive MOSFETs. It connects to the power source ground terminal.
This input selects between a positive or a negative speed control slope. When connected to ground, an
increasing voltage at Pin 6 or 10 increases motor speed. When not connected, an increasing voltage at Pin 6
or 10 decreases motor speed. This input has an internal 10 μA current source pull-up.
This output provides a digital square wave signal that switches at the Hall sensor frequency and is active low
when the voltage applied to the Hall - input exceeds that of the Hall +. If the motor turns too slow or is
stalled, the output will assume a high state. This is an active low open drain output and it requires a pull-up
resistor.
This output directly drives phase 1 of a unipolar motor. It is active low when the voltage applied to the Hall +
input exceeds that of Hall -.
Layout Considerations
High frequency printed circuit layout techniques are required to prevent pulse jitter and the possibility of erratic operation.
This can be caused by excessive noise pick-up imposed upon the Hall or Error Amplifier inputs. The printed circuit layout
should contain as much copper ground as possible with separate low current signal and high current motor drive grounds
that return back to the power supply input filter capacitor. Ceramic 0.1 µF bypass capacitors connected close to the
integrated circuit VDD and Vref pins may also be required depending upon circuit board layout and the source voltage
impedance. The use of bypass capacitors will provide a low impedance path to ground for filtering out high frequency noise.
The signal and power ground pins along with the exposed thermal pad must be connected together at the package. All high
current loops should be kept as short as possible with wide traces to minimize the generation of radiated electro magnetic
interference, EMI. Wide copper trace connections with copious amounts of foil placed under the device will greatly enhance
the devices ability to dissipate power.
© Andigilog, Inc. 2006
- 17 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Pin
Preliminary Specification
aMC8500
Figure 34- Thermistor Sensing Variable Speed Temperature Regulator
12 V
H
S
N
M
N
R1
Op Amp
7
T
R3
10 k
R5
@ 25°C
β = 3694
R4
1
Motor
Drives
Fault Timer
Power Down
Kick Start
8
S
16
Hall Amplifier
Non-Overlap
Commutation
R6
H
4
Under Voltage
Lockout
Reference
5
R2
3
15
Thermal
Shutdown
9
R8
6
R7
Current
Limit
Latch
Min Speed
Comp
Oscillator
R
PWM Comp
R
13
H
Q
PWM
Logic
10
2
S
Current Limit
Comp
Digital
Detector
10 nF
10 μA
11
Application Requirements
14
Closest Standard 1.0% Resistor Values
Tmin
Speed
PWM
Tmax
Speed
PWM
Minimum
Speed
Setting
°C
%on
°C
%on
%on
Ω
Ω
Ω
Ω
Ω
Ω
Ω
Ω
30
35
40
100
35
10000
6650
11500
32400
1130
1150
2550
1330
30
67
38
100
35
10000
6980
11500
16200
1870
1330
2550
1330
35
30
50
100
0
10000
4990
15400
29100
1370
1300
-
-
37
30
40
100
30
10000
5900
10200
133000
1000
1000
2910
1330
40
30
50
100
30
10000
4640
14700
49900
1000
1000
2910
1330
Thermistor
Linearization
R1
R2
Gain
R3
Offset
R4
R5
Min Speed
R6
R7
R8
The Op Amp used in conjunction with the Reference is extremely useful in providing voltage gain and offset to condition the thermistor
signal so that it can drive the Speed Control Input. The table shows five different application requirements with the calculated closest
standard 1.0% resistor values. In each example, the required motor speed or PWM %on is defined for two sensor temperatures along
with a minimum speed setting. In the third application, the minimum speed set input is not required and the comparator must be disabled
by connecting Pin 6 to Pin 14. Note that the total Reference load current must exceed 2.0 mA in order to disable the automatic power
down feature.
© Andigilog, Inc. 2006
- 18 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
12
Preliminary Specification
aMC8500
Figure 35- Simistor™ Sensing Variable Speed Temperature Regulator
12 V
H
S
N
M
N
Reference
5
R4
H
3
S
16
1
Under Voltage
Lockout
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Op Amp
aSM121
4
7
R1
R3
R2
Fault Timer
Power Down
Kick Start
8
15
Thermal
Shutdown
9
R6
R5
Current
Limit
Latch
Min Speed
Comp
6
Oscillator
R
H
13
R
PWM Comp
Q
PWM
Logic
10
2
S
Current Limit
Comp
Digital
Detector
10 nF
10 μA
14
11
Application Requirements
Closest Standard 1.0% Resistor Values
Tmax
Speed
PWM
Minimum
Speed
Setting
%on
°C
%on
%on
Ω
Ω
Ω
Ω
Ω
Ω
35
40
100
35
13700
16500
1400
5360
1070
1130
30
67
38
100
35
10500
76800
1370
6810
1070
1130
35
30
50
100
0
1070
8870
232
845
-
-
37
30
40
100
30
1070
48700
1330
4120
1070
1270
40
30
50
100
30
13000
169000
2320
7320
953
1130
Tmin
Speed
PWM
°C
30
Gain
R1
Offset
R2
R3
Min Speed
R4
R5
R6
This application circuit uses a Simistotr™ solid state silicon temperature sensor that provides a precision signal of 10 mV/°C with an
offset of 500 mV at 0°C. The Op Amp in conjunction with the Reference is used to gain-up and offset the signal before applying it to the
speed control input. The above table shows five application requirements that are similar to those in Figure 33 with the calculated
resistor values. The Simistor™ sensor allows a reduced component count when compared to the equivalent thermistor circuit. In each
example, the required PWM %on or motor speed is defined for a minimum and maximum sensor temperature, and for a minimum speed
setting. In the third application, the minimum speed set input is not required and the comparator must be disabled by connecting Pin 6 to
Pin 14. Note that the total Reference load current must exceed 2.0 mA in order to disable the automatic power down feature.
© Andigilog, Inc. 2006
- 19 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
12
Preliminary Specification
aMC8500
Figure 36- Thermistor Sensing Thermostatic Temperature Regulator
12 V
H
S
N
M
N
5
R4
4
7
R3
H
R1
T
R5
10 k
@ 25°C
β = 3694
R7
1
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Op Amp
S
16
Under Voltage
Lockout
Reference
R2
3
Fault Timer
Power Down
Kick Start
8
9
Current
Limit
Latch
Min Speed
Comp
6
R6
15
Thermal
Shutdown
Oscillator
R
PWM Comp
R
H
Q
PWM
Logic
10
2
S
Current Limit
Comp
Digital
Detector
10 nF
10 μA
14
11
Application Requirements
Speed Transition
Temperature °C
13
Closest Standard 1.0% Resistor Values
Minimum
Speed
Setting
Thermistor
Linearization
R1
R2
Threshold
R3
R4
Hysteresis
R5
Min Speed
R6
R7
Min to Max
Max to Min
%on
Ω
Ω
Ω
Ω
Ω
Ω
Ω
30
28
35
10000
8060
1020
1000
158000
1070
1130
35
30
35
10000
7500
1020
1100
66500
1070
1130
38
35
0
10000
6340
1020
1070
113000
-
-
40
38
30
10000
5760
1050
1100
180000
1070
1270
45
40
30
10000
4990
1050
1130
73200
1070
1270
Thermostatic control can be accomplished by configuring the Op Amp as a non-inverting voltage comparator. The above table shows
five different application examples with the calculated resistor values. In applications 1, 2, 4, and 5, the motor will switch from the
programmed minimum setting to maximum speed as the sensor temperature rises above the required transition temperature. A
controlled amount of positive feedback shifts the transition temperatures to provide thermal hysteresis as the sensor cools. In the third
application requirement, the motor speed switches between zero and full speed. In this case the minimum speed set input is not
required and the comparator must be disabled by connecting Pin 6 to Pin 14. Note that the total Reference load current must exceed 2.0
mA in order to disable the automatic power down feature.
© Andigilog, Inc. 2006
- 20 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
12
Preliminary Specification
aMC8500
Figure 37 Simistor™ Sensing Thermostatic Temperature Regulator
12 V
H
S
N
M
N
4
1
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Op Amp
S
16
Under Voltage
Lockout
Reference
5
R2
3
R1
aSM121
H
Fault Timer
Power Down
Kick Start
8
R3
15
Thermal
Shutdown
9
R5
6
R4
Current
Limit
Latch
Min Speed
Comp
Oscillator
R
PWM Comp
R
H
Q
PWM
Logic
10
S
2
Current Limit
Comp
Digital
Detector
10 nF
10 μA
11
14
Application Requirements
Speed Transition
Temperature °C
13
Closest Standard 1.0% Resistor Values
Minimum
Speed
Setting
Threshold
Hysteresis
Min Speed
R1
R2
R3
R4
Min to Max
Max to Min
%on
Ω
Ω
Ω
Ω
R5
Ω
30
28
35
499
1740
221000
2320
1210
35
30
35
215
715
40200
3240
1690
38
35
0
200
619
60400
-
-
40
38
30
187
562
68000
2490
1150
45
40
30
196
562
35700
2490
1150
Thermostatic control is achieved by configuring the Op Amp as a voltage comparator. The inverting input monitors the Simistor™ solid
state thermal sensor while the non-inverting input is biased to a reference level. The above table shows five different application
examples with the calculated resistor values. In applications 1, 2, 4, and 5, the motor speed switches from the programmed minimum
setting to maximum as the sensor temperature rises above the required transition temperature. A controlled amount of positive feedback
shifts the transition temperatures to provide thermal hysteresis as the sensor cools. In the third application requirement, the motor
switches between zero and full speed. In this case the minimum speed set input is not required and the comparator must be disabled by
connecting Pin 6 to Pin 14. Note that the total Reference load current must exceed 2.0 mA in order to disable the automatic power down
feature.
© Andigilog, Inc. 2006
- 21 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
12
Preliminary Specification
aMC8500
Figure 38- Balanced Technology Extended (BTX) Closed Loop Speed Control
12 V
H
S
N
M
Duty Cycle
to Voltage
Converter
10
k
H
Temperature
Controlled
Clamp
Ref
Op Amp
22 μF
FB
8
330 nF
Error
47 k
2.8 k
6.8 k
VDD
10 k
FGRL
Out
Fault Timer
Power Down
Kick Start
15
Thermal
Shutdown
9
SC
1M 6
13
Current
Limit
Latch
Min Speed
Comp
Oscillator
H
1
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
R
PWM Comp
20 k
T
S
16
Under Voltage
Lockout
Reference
7
6.8 k
74AC86PC
4
100 nF
5
330 nF
10 k
3
Q
PWM
Logic
10
S
2
Current Limit
Comp
Digital
Detector
10 nF
10 μA
Thermistor
(°C)
(Ω)
24
10464
25
10061
26
9712
28
9027
30
8394
32
7828
34
7291
36
6799
β = 3300
11
Frequency to Voltage Converter
100 k
10 nF
14
10 k
150 k
Figure 39- Fan Speed versus Control Signal Duty Cycle
for Various Inlet Air Temperatures
4800
36
Inlet Air Temperature °C
32
3200
30
2400
Min Speed Set
Intercept Points
1600
28
26
24
20%
800
70% Duty Cycle
2200
Fan Speed (RPM)
Fan Speed (RPM)
Control Signal = 0 to 5.0 V, 10 kHz
Inlet Air Temperature = 30°C
34
4000
0
2600
Figure 40- Fan Speed versus Motor Voltage
for Various Control Signal Duty Cycles
1800
50% Duty Cycle
1400
30% Duty Cycle
1000
10%
0
60
40
20
80
Control Signal Duty Cycle (%)
100
600
10.8
11.2
11.6
12.0 12.4 12.8
Motor Voltage (V)
13.2
13.6
The above circuit controls fan speed in a closed loop manner that is proportional to the control signal duty cycle and inlet air
temperature. A voltage indicating the required fan speed or Reference is applied to Pin 7 and is derived from the Duty Cycle to Voltage
Converter and Temperature Controlled Clamp circuits. The Duty Cycle to Voltage Converter consists of an XOR gate buffer that drives a
10 k, 22 μF low pass filter, with the high state level limited by the Temperature Controlled Clamp. A voltage indicating the actual fan
speed or Feedback is applied to Pin 8 and is derived from the Frequency to Voltage Converter that consists of two XOR gates. The first
XOR buffers the FGRL tachometer signal and connects to the second which is configured as an edge transition one-shot that drives a
100 k, 330 nF low pass filter. The Op Amp compares the difference between the Reference and Feedback voltages and generates an
Error signal that drives Pin 6 in a corrective fashion causing the fan to run either faster or slower so that the Feedback voltage level
becomes the same as the Reference. Performance data is shown in the above graphs. Note that the Error signal is applied to Pin 6
instead of Pin 10 and that Pin 10 must be biased between 1.0 V to 3.0 V for proper operation.
© Andigilog, Inc. 2006
- 22 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Control
Signal
Input
N
12
Preliminary Specification
aMC8500
Figure 41- Digital Pulse Speed Control with Programmable Minimum Speed Set
12 V
H
S
N
M
N
12
Reference
4
1
Under Voltage
Lockout
Motor
Drives
Hall Amplifier
Non-Overlap
Commutation
Op Amp
7
Fault Timer
Power Down
Kick Start
8
S
16
15
Thermal
Shutdown
9
453
909
6
Oscillator
R
6.2 k
36 k
2.7 k
Pulse
Input 10 k
C1
0.1
Current
Limit
Latch
Min Speed
Comp
R
PWM Comp
Q
PWM
Logic
10
Q1
13
2
S
Current Limit
Comp
Digital
Detector
10 nF
10 μA
14
11
The programmable minimum speed set feature can be preserved when controlling motor speed from a varying duty cycle pulse. The
above circuit uses transistor Q1, capacitor C1 and the Reference to convert the digital control signal to an analog voltage. With the
resistor values shown, the voltage at Pin 10 varies between 3.0 V with Q1 off and 1.0 V with Q1 on, which represents a PWM on-time of
0% and 100% respectively. The value of capacitor C1 is dependent upon the pulse frequency and should be sized be so that the ripple
at Pin 10 is less than 10 mV. The Op Amp is not required in this application and is connected as a unity gain follower with the noninverting grounded. The Minimum Speed Set input is programmed for a PWM on-time of approximately 33%. Since the Reference is
always required, the programming resistors also provide a load that exceeds 2.0 mA for disabling the automatic power down feature.
Figure 42- Speed Control Alarm
5
R2
Op Amp
7
Vth
Speed
Alarm
Output
R1
VOH
VOL
Vth
0V
Reference
3.0 V
R2
9
Oscillator
Min Speed
Comp
PWM Comp
9
3.0 V
Speed
Control
Input
10
7
8
VOL
Vth
0V
Reference
Op Amp
R1
VOH
6
5
Vth
Speed
Alarm
Output
8
R
Speed
Control
Input
Pin 11 = Gnd
Vth = 1 + 0.02(%ton)
Pin 11 = Open
Vth = 3 - 0.02(%ton)
R2/R1 = (Vref / Vth) - 1
6
Oscillator
R
Min Speed
Comp
PWM Comp
10
The Op Amp and Reference can be used to generate a speed control alarm signal. Resistors R1 and R2 divide down the Reference
output voltage to set trip threshold Vth. The Op Amp compares the speed control input voltage to the trip threshold and the output
changes state when it is crossed. In the circuit on the left, the speed alarm output transitions from a low to high state as the Speed
Control Input voltage increases. With the circuit on the right, the speed alarm output transitions from a high to low state as the speed
control input voltage increases. Threshold hysteresis can be added to the circuit on the right by placing a resistor from Pin 9 to Pin 7.
© Andigilog, Inc. 2006
- 23 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
5
3
Preliminary Specification
aMC8500
Figure 43- Dual Fan Redundancy
12 V
H
M
12
R2
590
C1
1.0
Ref
5
16
UVLO
1
Drives
Hall Amp
Commutation
Op Amp
7
4
Timers
Power Down
8
15
TSD
9
Min Spd
6
Osc
R3
787
Latch
PWM
13
R
Q
PWM
Logic
10
2
S
10 nF
Current Limit
Digital
Detector
10 μA
11
14
12 V
H
M
1
16
4
3
12
Hall Amp
Commutation
15
Ref
UVLO
Drives
Op Amp
Timers
Power Down
TSD
5
R2
590
R1
1.0 M
C1
1.0
7
8
9
Min Spd
Latch
13
R
Q
10 nF
PWM
Logic
S
2
6
Osc
PWM
10
R3
787
Current Limit
Digital
Detector
10 μA
14
11
In applications that require increased system reliability, multiple cooling fans can be employed for redundancy. In this example two
aMC8500s are cross coupled so that each device drives a fan while monitoring operation of the other. Resistors R2 and R3 program the
Speed Control inputs to operate each fan at a 50% speed. During normal operation, the Frequency Generator / Rotor Lock outputs,
Pin 15, continuously discharges their respective C1 capacitors. In the event that one fan should fail, Pin 15 will allow R1 to charge C1
above 2.0 V. This causes the Op Amp output to drive the Minimum Speed Set input above 3.0 V for maximum speed on the remaining
fan. The values for resistors R2 and R3 are chosen so that each Reference Output is loaded in excess of 2.0 mA in order to disable the
automatic power down feature.
© Andigilog, Inc. 2006
- 24 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
R1
1.0 M
3
Preliminary Specification
aMC8500
Top View
Bottom View
Side View
End View
Detail A
© Andigilog, Inc. 2006
- 25 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Figure 44- QSOP16 Package Outline Drawing
Preliminary Specification
aMC8500
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
Figure 45- SOIC16 Exposed Pad Package Outline Drawing
© Andigilog, Inc. 2006
- 26 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification
aMC8500
Data Sheet Classifications
Preliminary Specification
This classification is shown on the heading of each page of a specification for products that are either under
development (design and qualification), or in the formative planning stages. Andigilog reserves the right to
change or discontinue these products without notice.
This classification is shown on the heading of the first page only of a specification for products that are either
under the later stages of development (characterization and qualification), or in the early weeks of release to
production. Andigilog reserves the right to change the specification and information for these products without
notice.
Fully Released Specification
Fully released datasheets do not contain any classification in the first page header. These documents contain
specification on products that are in full production. Andigilog will not change any guaranteed limits without
written notice to the customers. Obsolete datasheets that were written prior to January 1, 2001 without any
header classification information should be considered as obsolete and non-active specifications, or in the best
case as Preliminary Specifications.
LIFE SUPPORT POLICY
ANDIGILOG'S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES
OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF
ANDIGILOG, INC. As used herein:
1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b)
support or sustain life, and whose failure to perform when properly used in accordance with instructions for use provided in
the labeling, can be reasonably expected to result in a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably
expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.
Andigilog, Inc.
8380 S. Kyrene Rd., Suite 101
Tempe, Arizona 85284
Tel: (480) 940-6200
Fax: (480) 940-4255
© Andigilog, Inc. 2006
- 27 www.andigilog.com
August 2006 - 70A04018
Preliminary Specification – Subject to change without notice
Preliminary Specification – Subject to change without notice
New Release Specification