MC33035DWR2G - ON SEMICONDUCTOR - Datasheet.Directory

April, 2006 − Rev. 8 1Publication Order Number:

MC33035/D

MC33035, NCV33035

Brushless DC

Motor Controller

The MC33035 is a high performance second generation monolithic

brushless DC motor controller containing all of the active functions

required to implement a full featured open loop, three or four phase

motor control system. This device consists of a rotor position decoder

for proper commutation sequencing, temperature compensated

reference capable of supplying sensor power, frequency

programmable sawtooth oscillator, three open collector top drivers,

and three high current totem pole bottom drivers ideally suited for

driving power MOSFETs.

Also included are protective features consisting of undervoltage

lockout, cycle−by−cycle current limiting with a selectable time

delayed latched shutdown mode, internal thermal shutdown, and a

unique fault output that can be interfaced into microprocessor

controlled systems.

Typical motor control functions include open loop speed, forward or

reverse direction, run enable, and dynamic braking. The MC33035 is

designed to operate with electrical sensor phasings of 60°/300° or

120°/240°, and can also efficiently control brush DC motors.

Features

•10 to 30 V Operation

•Undervoltage Lockout

•6.25 V Reference Capable of Supplying Sensor Power

•Fully Accessible Error Amplifier for Closed Loop Servo

Applications

•High Current Drivers Can Control External 3−Phase MOSFET

Bridge

•Cycle−By−Cycle Current Limiting

•Pinned−Out Current Sense Reference

•Internal Thermal Shutdown

•Selectable 60°/300° or 120°/240° Sensor Phasings

•Can Efficiently Control Brush DC Motors with External MOSFET

H−Bridge

•NCV Prefix for Automotive and Other Applications Requiring Site

and Control Changes

•Pb−Free Packages are Available

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Top Drive

Output

Bottom

Drive

Outputs

(Top View)

Sensor

Inputs

Oscillator

Current Sense

Noninverting Input

Reference Output

Output Enable

60°/120°SelectFwd/Rev

Current Sense

Inverting Input

Gnd

VCC

Brake

PIN CONNECTIONS

P SUFFIX

PLASTIC PACKAGE

CASE 724

DW SUFFIX

PLASTIC PACKAGE

CASE 751E

(SO−24L)

1312

Error Amp

Inverting Input

Error Amp

Noninverting Input

Error Amp Out/

PWM Input

Fault Output

See detailed ordering and shipping information in the packag

dimensions section on page 27 of this data sheet.

ORDERING INFORMATION

See general marking information in the device marking

section on page 27 of this data sheet.

DEVICE MARKING INFORMATION

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Motor

Enable

Oscillator

Error Amp

PWM

Thermal

Shutdown

Reference

Regulator

Lockout

Undervoltage

Vin

Fwd/Rev

Faster

Speed

Set

This device contains 285 active transistors.

Representative Schematic Diagram

Rotor

Position

Decoder

Output

Buffers

Current Sense

Reference

60°/120°

Brake

Fault N

2316

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MAXIMUM RATINGS

Rating Symbol Value Unit

Power Supply Voltage VCC 40 V

Digital Inputs (Pins 3, 4, 5, 6, 22, 23) − Vref V

Oscillator Input Current (Source or Sink) IOSC 30 mA

Error Amp Input Voltage Range (Pins 11, 12, Note 1) VIR −0.3 to Vref V

Error Amp Output Current (Source or Sink, Note 2) IOut 10 mA

Current Sense Input Voltage Range (Pins 9, 15) VSense −0.3 to 5.0 V

Fault Output Voltage VCE(Fault)20 V

Fault Output Sink Current ISink(Fault)20 mA

Top Drive Voltage (Pins 1, 2, 24) VCE(top) 40 V

Top Drive Sink Current (Pins 1, 2, 24) ISink(top) 50 mA

Bottom Drive Supply Voltage (Pin 18) VC30 V

Bottom Drive Output Current (Source or Sink, Pins 19, 20, 21) IDRV 100 mA

Power Dissipation and Thermal Characteristics

P Suffix, Dual In Line, Case 724

Maximum Power Dissipation @ TA = 85°C

Thermal Resistance, Junction−to−Air

DW Suffix, Surface Mount, Case 751E

Maximum Power Dissipation @ TA = 85°C

Thermal Resistance, Junction−to−Air

RθJA

867

650

100

°C/W

Operating Junction Temperature TJ150 °C

Operating Ambient Temperature Range (Note 3) MC33035

NCV33035 TA−40 to +85

−40 to +125 °C

Storage Temperature Range Tstg −65 to +150 °C

Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the

Recommended O p e r a t i n g Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect

device reliability.

ELECTRICAL CHARACTERISTICS (VCC = VC = 20 V, RT = 4.7 k, CT = 10 nF, TA = 25°C, unless otherwise noted.)

Characteristic Symbol Min Typ Max Unit

REFERENCE SECTION

Reference Output Voltage (Iref = 1.0 mA)

TA = 25°C

(Note 4)

Vref 5.9

5.82 6.24

−6.5

6.57

Line Regulation (VCC = 10 to 30 V, Iref = 1.0 mA) Regline − 1.5 30 mV

Load Regulation (Iref = 1.0 to 20 mA) Regload − 16 30 mV

Output Short Circuit Current (Note 5) ISC 40 75 − mA

Reference Under Voltage Lockout Threshold Vth 4.0 4.5 5.0 V

ERROR AMPLIFIER

Input Offset Voltage (Note 4) VIO − 0.4 10 mV

Input Offset Current (Note 4) IIO − 8.0 500 nA

Input Bias Current (Note 4) IIB −−46 −1000 nA

Input Common Mode Voltage Range VICR (0 V to Vref) V

Open Loop Voltage Gain (VO = 3.0 V, RL = 15 k) AVOL 70 80 − dB

Input Common Mode Rejection Ratio CMRR 55 86 − dB

Power Supply Rejection Ratio (VCC = VC = 10 to 30 V) PSRR 65 105 − dB

1. The input common mode voltage or input signal voltage should not be allowed to go negative by more than 0.3 V.

2. The compliance voltage must not exceed the range of −0.3 to Vref.

3. NCV33035: Tlow = − 40°C, Thigh = 125°C. Guaranteed by design. NCV prefix is for automotive and other applications requiring site and change

control.

4. MC33035: TA = −40°C to +85°C; NCV33035: TA = −40°C to +125°C.

5. Maximum package power dissipation limits must be observed.

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ELECTRICAL CHARACTERISTICS (continued) (VCC = VC = 20 V, RT = 4.7 k, CT = 10 nF, TA = 25°C, unless otherwise noted.)

Characteristic Symbol Min Typ Max Unit

ERROR AMPLIFIER

Output Voltage Swing

High State (RL = 15 k to Gnd)

Low State (RL = 15 k to Vref)VOH

VOL 4.6

−5.3

0.5 −

1.0

OSCILLATOR SECTION

Oscillator Frequency fOSC 22 25 28 kHz

Frequency Change with Voltage (VCC = 10 to 30 V) ΔfOSC/ΔV − 0.01 5.0 %

Sawtooth Peak Voltage VOSC(P) − 4.1 4.5 V

Sawtooth Valley Voltage VOSC(V) 1.2 1.5 − V

LOGIC INPUTS

Input Threshold Voltage (Pins 3, 4, 5, 6, 7, 22, 23)

High State

Low State VIH

VIL 3.0

−2.2

1.7 −

0.8

Sensor Inputs (Pins 4, 5, 6)

High State Input Current (VIH = 5.0 V)

Low State Input Current (VIL = 0 V) IIH

IIL −150

−600 −70

−337 −20

−150

μA

Forward/Reverse, 60°/120° Select (Pins 3, 22, 23)

High State Input Current (VIH = 5.0 V)

Low State Input Current (VIL = 0 V) IIH

IIL −75

−300 −36

−175 −10

−75

μA

Output Enable

High State Input Current (VIH = 5.0 V)

Low State Input Current (VIL = 0 V) IIH

IIL −60

−60 −29

−29 −10

−10

μA

CURRENT−LIMIT COMPARATOR

Threshold Voltage Vth 85 101 115 mV

Input Common Mode Voltage Range VICR − 3.0 − V

Input Bias Current IIB − −0.9 −5.0 μA

OUTPUTS AND POWER SECTIONS

Top Drive Output Sink Saturation (Isink = 25 mA) VCE(sat) − 0.5 1.5 V

Top Drive Output Off−State Leakage (VCE = 30 V) IDRV(leak) − 0.06 100 μA

Top Drive Output Switching Time (C L = 47 pF, RL = 1.0 k) ns

Rise Time tr− 107 300

Fall Time tf− 26 300

Bottom Drive Output Voltage

High State (VCC = 20 V, VC = 30 V, Isource = 50 mA)

Low State (VCC = 20 V, VC = 30 V, Isink = 50 mA) VOH

VOL (VCC −2.0)

−(VCC −1.1)

1.5 −

2.0

Bottom Drive Output Switching Time (CL = 1000 pF) ns

Rise Time tr− 38 200

Fall Time tf− 30 200

Fault Output Sink Saturation (Isink = 16 mA) VCE(sat) − 225 500 mV

Fault Output Of f−State Leakage (V CE = 20 V) IFLT(leak) − 1.0 100 μA

Under Voltage Lockout V

Drive Output Enabled (VCC or VC Increasing) Vth(on) 8.2 8.9 10

Hysteresis VH0.1 0.2 0.3

Power Supply Current

Pin 17 (VCC = VC = 20 V)

Pin 17 (VCC = 20 V, VC = 30 V)

Pin 18 (VCC = VC = 20 V)

Pin 18 (VCC = 20 V, VC = 30 V)

ICC

−

3.5

5.0

6.0

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Vsat, OUTPUT SATURATION VOLTAGE (V)

5.0 μs/DIV

AV = +1.0

No Load

TA = 25°C

, OUTPUT VOLTAGE (V)

4.5

3.0

1.5

1.0 μs/DIV

AV = +1.0

No Load

TA = 25°C

3.05

3.0

2.95

Gnd

Vref

IO, OUTPUT LOAD CURRENT (mA)

f, FREQUENCY (Hz)

1.0 k

220

200

180

160

140

120

100

−24

−16

− 8.0

8.0

10 M1.0 M100 k10 k

240

AVOL, OPEN LOOP VOLTAGE GAIN (dB)

EXCESS PHASE (DEGREES)

Phase

Gain

TA, AMBIENT TEMPERATURE (°C)

−55

− 4.0

− 2.0

2.0

125

4.0

1007550250−25

OSC OSCILLATOR FREQUENCY CHANGE (%)

,Δ

100

CT = 1.0 nF

CT = 100 nF

1.0

RT, TIMING RESISTOR (kΩ)

100010010

OSC OSCILLATOR FREQUENCY (kHz)

CT = 10 nF

Figure 1. Oscillator Frequency versus

Timing Resistor Figure 2. Oscillator Frequency Change

versus Temperature

Figure 3. Error Amp Open Loop Gain and

Phase versus Frequency Figure 4. Error Amp Output Saturation

Voltage versus Load Current

Figure 5. Error Amp Small−Signal

Transient Response Figure 6. Error Amp Large−Signal

Transient Response

1.0 2.0

− 0.8

−1.6

1.6

0.8

5.04.03.00

VCC = 20 V

VC = 20 V

TA = 25°C

VCC = 20 V

VC = 20 V

RT = 4.7 k

CT = 10 nF

Source Saturation

(Load to Ground)

VCC = 20 V

VC = 20 V

TA = 25°C

Sink Saturation

(Load to Vref)

, OUTPUT VOLTAGE (V)

VCC = 20 V

VC = 20 V

VO = 3.0 V

RL = 15 k

CL = 100 pF

TA = 25°C

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, OUTPUT SATURATION VOLTAGE (V)Vsat

ISink, SINK CURRENT (mA)

016128.04.0

0.25

0.2

0.05

TA, AMBIENT TEMPERATURE (°C)

−25

−40

−20

−55 0

125100755025

, NORMALIZED REFERENCE VOLTAGE CHANGE (mV)ΔVref

Iref, REFERENCE OUTPUT SOURCE CURRENT (mA)

605040302010

−24

−20

− 4.0

− 8.0

− 12

− 16

Vref, REFERENCE OUTPUT VOLTAGE CHANGE (mV)Δ

Figure 7. Reference Output Voltage Change

versus Output Source Current Figure 8. Reference Output Voltage

versus Supply Voltage

Figure 9. Reference Output Voltage

versus Temperature Figure 10. Output Duty Cycle versus

PWM Input Voltage

Figure 11. Bottom Drive Response Time versus

Current Sense Input Voltage Figure 12. Fault Output Saturation

versus Sink Current

7.0

VCC, SUPPLY VOLTAGE (V)

6.0

40302010

5.0

4.0

3.0

2.0

1.0

Vref, REFERENCE OUTPUT VOLTAGE (V)

5.04.03.02.01.0

100

PWM INPUT VOLTAGE (V)

OUTPUT DUTY CYCLE (%)

CURRENT SENSE INPUT VOLTAGE (NORMALIZED TO Vth)

100

150

200

250

1.0 2.0 3.0 4.0 5.0 7.0 8.0 10

tHL, BOTTOM DRIVE RESPONSE TIME (ns)

No Load

TA = 25°C

VCC = 20 V

VC = 20 V

No Load

6.0 9.0

VCC = 20 V

VC = 20 V

TA = 25°C

VCC = 20 V

VC = 20 V

RT = 4.7 k

CT = 10 nF

TA = 25°C

VCC = 20 V

VC = 20 V

RL = 1

CL = 1.0 nF

TA = 25°C0.15

0.1

VCC = 20 V

VC = 20 V

TA = 25°C

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1.0

OUTPUT VOLTAGE (%)

Gnd

− 2.0

IO, OUTPUT LOAD CURRENT (mA)

−1.0

2.0

806020

, OUTPUT SATURATION VOLTAGE (V)

sat

Sink Saturation

(Load to VC)

Source Saturation

(Load to Ground)

VCC = 20 V

VC = 20 V

TA = 25°C

VCC = 20 V

VC = 20 V

TA = 25°C

50 ns/DIV

VCC = 20 V

VC = 20 V

CL = 1.0 nF

TA = 25°C

100 ns/DIV

VCC = 20 V

VC = 20 V

RL = 1.0 k

CL = 15 pF

TA = 25°C

Figure 13. Top Drive Output Saturation

Voltage versus Sink Current Figure 14. Top Drive Output Waveform

Figure 15. Bottom Drive Output Waveform Figure 16. Bottom Drive Output Waveform

ISink, SINK CURRENT (mA)

10 30 40

0.4

0.8

1.2

Vsat, OUTPUT SATURATION VOLTAGE (V)

Figure 17. Bottom Drive Output Saturation

Voltage versus Load Current

50 ns/DIV

VCC = 20 V

VC = 20 V

CL = 15 pF

TA = 25°C

Figure 18. Power and Bottom Drive Supply

Current versus Supply Voltage

8.0

6.0

4.0

2.0

, POWER SUPPLY CURRENT (mA)

, I

0 5.0 10 15 20 25 30

RT = 4.7 k

CT = 10 nF

Pins 3−6, 9, 15, 23 = Gnd

Pins 7, 22 = Open

TA = 25°C

VCC, SUPPLY VOLTAGE (V)

ICC

100

OUTPUT VOLTAGE (%) OUTPUT VOLTAGE (%)

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PIN FUNCTION DESCRIPTION

Pin Symbol Description

1, 2, 24 BT, AT, CTThese three open collector Top Drive outputs are designed to drive the external

upper power switch transistors.

3 Fwd/Rev The Forward/Reverse Input is used to change the direction of motor rotation.

4, 5, 6 SA, SB, SCThese three Sensor Inputs control the commutation sequence.

7Output Enable A logic high at this input causes the motor to run, while a low causes it to coast.

8Reference Output This output provides charging current for the oscillator timing capacitor CT and a

reference for the error amplifier. It may also serve to furnish sensor power.

9Current Sense Noninverting Input A 100 mV signal, with respect to Pin 15, at this input terminates output switch

conduction during a given oscillator cycle. This pin normally connects to the top

side of the current sense resistor.

10 Oscillator The Oscillator frequency is programmed by the values selected for the timing

components, RT and CT.

11 Error Amp Noninverting Input This input is normally connected to the speed set potentiometer.

12 Error Amp Inverting Input This input is normally connected to the Error Amp Output in open loop

applications.

13 Error Amp Out/PWM Input This pin is available for compensation in closed loop applications.

14 Fault Output This open collector output is active low during one or more of the following

conditions: Invalid Sensor Input code, Enable Input at logic 0, Current Sense

Input greater than 100 mV (Pin 9 with respect to Pin 15), Undervoltage Lockout

activation, and Thermal Shutdown.

15 Current Sense Inverting Input Reference pin for internal 100 mV threshold. This pin is normally connected to

the bottom side of the current sense resistor.

16 Gnd This pin supplies a ground for the control circuit and should be referenced back

to the power source ground.

17 VCC This pin is the positive supply of the control IC. The controller is functional over a

minimum VCC range of 10 to 30 V.

18 VCThe high state (VOH) of the Bottom Drive Outputs is set by the voltage applied to

this pin. The controller is operational over a minimum VC range of 10 to 30 V.

19, 20, 21 CB, BB, ABThese three totem pole Bottom Drive Outputs are designed for direct drive of the

external bottom power switch transistors.

22 60°/120° Select The electrical state of this pin configures the control circuit operation for either

60° (high state) or 120°(low state) sensor electrical phasing inputs.

23 Brake A logic low state at this input allows the motor to run, while a high state does not

allow motor operation and if operating causes rapid deceleration.

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INTRODUCTION

The MC33035 is one of a series of high performance

monolithic DC brushless motor controllers produced by

Motorola. It contains all of the functions required to

implement a full−featured, open loop, three or four phase

motor control s ystem. In addition, the controller can be made

to operate DC brush motors. Constructed with Bipolar

Analog t echnology , i t of fers a h igh degree of p erformance and

ruggedness i n h ostile i ndustrial e nvironments. T he M C33035

contains a rotor position decoder for proper commutation

sequencing, a temperature c ompensated reference capable of

supplying a sensor power, a frequency programmable

sawtooth oscillator, a fully accessible e rror amplifier, a pulse

width modulator comparator, three open collector top drive

outputs, and three high current totem pole bottom driver

outputs ideally suited for driving power MOSFETs.

Included in the MC33035 are protective features

consisting of undervoltage lockout, cycle−by−cycle current

limiting with a selectable time delayed latched shutdown

mode, internal thermal shutdown, and a unique fault output

that can easily be interfaced to a microprocessor controller.

Typical motor control functions include open loop speed

control, forward or reverse rotation, run enable, and

dynamic braking. In addition, the MC33035 has a 60°/120°

select pin which configures the rotor position decoder for

either 60° or 120° sensor electrical phasing inputs.

FUNCTIONAL DESCRIPTION

A representative internal block diagram is shown in

Figure 19 with various applications shown in Figures 36, 38,

39, 43, 45, and 46. A discussion of the features and function

of each of the internal blocks given below is referenced to

Figures 19 and 36.

Rotor Position Decoder

An internal rotor position decoder monitors the three

sensor inputs (Pins 4, 5, 6) to provide the proper sequencing

of the top and bottom drive outputs. The sensor inputs are

designed to interface directly with open collector type Hall

Effect switches or opto slotted couplers. Internal pull−up

resistors are included to minimize the required number of

external components. The inputs are TTL compatible, with

their thresholds typically at 2.2 V. The MC33035 series is

designed t o control three phase motors and operate with four

of the most common conventions of sensor phasing. A

60°/120°Select (Pin 22) is conveniently provided and

affords the MC33035 to configure itself to control motors

having either 60°, 120°, 240° or 300° electrical sensor

phasing. With three sensor inputs there are eight possible

input code combinations, six of which are valid rotor

positions. The remaining two codes are invalid and are

usually caused by an open or shorted sensor line. With six

valid input codes, the decoder can resolve the motor rotor

position to within a window of 60 electrical degrees.

The Forward/Reverse input (Pin 3) is used to change the

direction of motor rotation by reversing the voltage across

the stator winding. When the input changes state, from high

to low with a given sensor input code (for example 100), the

enabled top and bottom drive outputs with the same alpha

designation are exchanged (AT to AB, BT to BB, CT to CB).

In effect, the commutation sequence is reversed and the

motor changes directional rotation.

Motor on/off control is accomplished by the Output

Enable (Pin 7). When left disconnected, an internal 25 μA

current source enables sequencing of the top and bottom

drive outputs. When grounded, the top drive outputs turn of f

and the bottom drives are forced low, causing the motor to

coast and the Fault output to activate.

Dynamic motor braking allows an additional margin of

safety to be designed into the final product. Braking is

accomplished by placing the Brake Input (Pin 23) in a high

state. This causes the top drive outputs to turn off and the

bottom drives to turn on, shorting the motor−generated back

EMF. The brake input has unconditional priority over all

other inputs. The internal 40 kΩ pull−up resistor simplifies

interfacing with the system safety−switch by insuring brake

activation if opened or disconnected. The commutation

logic truth table is shown in Figure 20. A four input NOR

gate is used to monitor the brake input and the inputs to the

three top drive output transistors. Its purpose is to disable

braking until the top drive outputs attain a high state. This

helps to prevent simultaneous conduction of the the top and

bottom power switches. In half wave motor drive

applications, the top drive outputs are not required and are

normally left disconnected. Under these conditions braking

will still be accomplished since the NOR gate senses the

base voltage to the top drive output transistors.

Error Amplifier

A high performance, fully compensated error amplifier

with access to both inputs and output (Pins 11, 12, 13) is

provided to facilitate the implementation of closed loop

motor speed control. The amplifier features a typical DC

voltage gain of 80 dB, 0.6 MHz gain bandwidth, and a wide

input common m ode v oltage range t hat e xtends f rom g round

to Vref. In most open loop speed control applications, the

amplifier is configured as a unity gain voltage follower with

the noninverting input connected to the speed set voltage

source. Additional configurations are shown in Figures 31

through 35.

Oscillator

The frequency of the internal ramp oscillator is

programmed by the values selected for timing components

RT and CT. Capacitor CT is charged from the Reference

Output (Pin 8) through resistor RT and discharged by an

internal discharge transistor. The ramp peak and valley

voltages are typically 4.1 V and 1.5 V respectively. To

provide a good compromise between audible noise and

output switching efficiency, an oscillator frequency in the

range of 2 0 t o 3 0 kHz is recommended. Refer to Figure 1 for

component selection.

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Top

Drive

Outputs

Bottom

Drive

Outputs

Current Sense

Reference Input

Oscillator

Error Amp

PWM

Thermal

Shutdown

Reference

Regulator

Lockout

Undervoltage

Rotor

Position

Decoder

Brake Input

Figure 19. Representative Block Diagram

60°/120°Select

Output Enable

Vin

Forward/Reverse

Faster

Noninv. Input

Sensor

Inputs

Error Amp Out

PWM Input

Sink Only

Positive True

Logic With

Hysteresis

Reference Output

Latch

23Gnd

9Current Sense Input

Fault Output

20 k

40 k

25 μA

VCC

9.1 V

4.5 V

100 mV

40 k

Inputs (Note 2) Outputs (Note 3)

Sensor Electrical Phasing (Note 4) Top Drives Bottom Drives

SA60°

SBSCSA120°

SBSCF/R Enable Brake Current

Sense ATBTCTABBBCBFault

(Note 5)

F/R = 1

(Note 5)

F/R = 0

0(Note 6)

Brake = 0

0(Note 7)

Brake = 1

V V V V V V X 1 1 X 1 1 1 1 1 1 1 (Note 8)

V V V V V V X 0 1 X 1 1 1 1 1 1 0 (Note 9)

V V V V V V X 0 0 X 1 1 1 0 0 0 0 (Note 10)

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V V V V V V X 1 0 1 1 1 1 0 0 0 0 (Note 11)

NOTES: 1. V = Any one of six valid sensor or drive combinations X = Don’t care.

2. The digital inputs (Pins 3, 4, 5, 6, 7, 22, 23) are all TTL compatible. The current sense input (Pin 9) has a 100 mV threshold with respect to Pin 15.

A logic 0 for this input is defined as < 85 mV, and a logic 1 is > 115 mV.

3. The fault and top drive outputs are open collector design and active in the low (0) state.

4. With 60°/120°select (Pin 22) in the high (1) state, configuration is for 60°sensor electrical phasing inputs. With Pin 22 in low (0) state, configuration

is for 120° sensor electrical phasing inputs.

5. Valid 60° or 120° sensor combinations for corresponding valid top and bottom drive outputs.

6. Invalid sensor inputs with brake = 0; All top and bottom drives off, Fault low.

7. Invalid sensor inputs with brake = 1; All top drives off, all bottom drives on, Fault low.

8. Valid 60° or 120°sensor inputs with brake = 1; All top drives off, all bottom drives on, Fault high.

9. Valid sensor inputs with brake = 1 and enable = 0; All top drives off, all bottom drives on, Fault low.

10. Valid sensor inputs with brake = 0 and enable = 0; All top and bottom drives off, Fault low.

11. All bottom drives off, Fault low.

Figure 20. Three Phase, Six Step Commutation Truth Table (Note 1)

Pulse Width Modulator

The use of pulse width modulation provides an energy

efficient method of controlling the motor speed by varying

the average voltage applied to each stator winding during the

commutation sequence. As CT discharges, the oscillator sets

both latches, allowing conduction of the top and bottom

drive outputs. The PWM comparator resets the upper latch,

terminating the bottom drive output conduction when the

positive−going ramp of CT becomes greater than the error

amplifier output. The pulse width modulator timing diagram

is shown in Figure 21. Pulse width modulation for speed

control appears only at the bottom drive outputs.

Current Limit

Continuous operation of a motor that is severely

over−loaded results in overheating and eventual failure.

This destructive condition can best be prevented with the use

of cycle−by−cycle current limiting. That is, each on−cycle

is treated as a separate event. Cycle−by−cycle current

limiting is accomplished by monitoring the stator current

build−up each time an output switch conducts, and upon

sensing an over current condition, immediately turning off

the switch and holding it off for the remaining duration of

oscillator ramp−up period. The stator current is converted to

a voltage by inserting a ground−referenced sense resistor RS

(Figure 36) in series with the three bottom switch transistors

(Q4, Q5, Q6). The voltage developed across the sense

resistor is monitored by the Current Sense Input (Pins 9 and

15), and compared to the internal 100 mV reference. The

current sense comparator inputs have an input common

mode range of approximately 3.0 V. If the 100 mV current

sense threshold is exceeded, the comparator resets the lower

sense latch and terminates output switch conduction. The

value for the current sense resistor is:

RS+0.1

Istator(max)

The Fault output activates during an over current condition.

The dual−latch PWM configuration ensures that only one

single output conduction pulse occurs during any given

oscillator cycle, whether terminated by the output of the

error amp or the current limit comparator.

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Figure 21. Pulse Width Modulator Timing Diagram

Current

Sense Input

Capacitor CT

Error Amp

Out/PWM

Input

Latch Set"

Inputs

Top Drive

Outputs

Bottom Drive

Outputs

Fault Output

Reference

The on−chip 6.25 V regulator (Pin 8) provides charging

current for t h e o s cillator timing capacitor, a reference for the

error amplifier, and can supply 2 0 mA of current suitable for

directly powering sensors in low voltage applications. In

higher voltage applications, it may become necessary to

transfer the power dissipated by the regulator of f the IC. This

is easily accomplished with the addition of an external pass

transistor as shown in Figure 22. A 6.25 V reference level

was chosen to allow implementation of the simpler NPN

circuit, where Vref − VBE exceeds the minimum voltage

required by Hall Effect sensors over temperature. With

proper transistor selection and adequate heatsinking, up to

one amp of load current can be obtained.

Figure 22. Reference Output Buffers

The NPN circuit is recommended for powering Hall or opto sensors, where

the output voltage temperature coefficient is not critical. The PNP circuit is

slightly more complex, but is also more accurate over temperature. Neither

circuit has current limiting.

Control

Circuitry

6.25 V

Sensor

Power

≈5.6 V

MPS

U51A

Vin

MPS

U01A

Vin

To Control Circuitry

and Sensor Power

6.25 V

UVLO

REF

0.1

REF

UVLO

Undervoltage Lockout

A triple Undervoltage Lockout has been incorporated to

prevent damage to the IC and the external power switch

transistors. Under low power supply conditions, it

guarantees that the IC and sensors are fully functional, and

that there is sufficient bottom drive output voltage. The

positive power supplies to the IC (VCC) and the bottom

drives ( V C) are each monitored by separate comparators that

have their thresholds at 9.1 V. This level ensures sufficient

gate drive necessary to attain low RDS(on) when driving

standard power MOSFET devices. When directly powering

the Hall sensors from the reference, improper sensor

operation can result if the reference output voltage falls

below 4.5 V. A third comparator is used to detect this

condition. If one or more of the comparators detects an

undervoltage condition, the Fault Output is activated, the top

drives are turned off and the bottom drive outputs are held

in a low state. Each of the comparators contain hysteresis to

prevent oscillations when crossing their respective

thresholds.

Fault Output

The open collector Fault Output (Pin 14) was designed to

provide diagnostic information in the event of a system

malfunction. It has a sink current capability of 16 mA and

can directly drive a light emitting diode for visual indication.

Additionally, it is easily interfaced with TTL/CMOS logic

for use in a microprocessor controlled system. The Fault

Output is active low when one or more of the following

conditions occur:

1) Invalid Sensor Input code

2) Output Enable at logic [0]

3) Current Sense Input greater than 100 mV

4) Undervoltage Lockout, activation of one or more of

the comparators

5) Thermal Shutdown, maximum junction temperature

being exceeded

This u nique o utput c an also be u sed t o d istinguish b etween

motor start−up or sustained operation in an overloaded

condition. With the addition of an RC network between the

Fault Output and the enable input, it is possible to create a

time−delayed latched shutdown for overcurrent. The added

circuitry shown in Figure 23 makes easy starting of motor

systems which have high inertial loads by providing

additional starting torque, while still preserving overcurrent

protection. This task is accomplished by setting the current

limit t o a h igher t han n ominal value for a p redetermined t ime.

During an excessively long overcurrent condition, capacitor

CDLY will charge, causing the enable input to cross its

threshold t o a l ow s tate. A l atch i s t hen formed b y t he p ositive

feedback loop from the Fault Output to the Output Enable.

Once set, by the Current Sense Input, it can only be reset by

shorting CDLY or cycling the power supplies.

MC33035, NCV33035

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Drive Outputs

The three top drive outputs (Pins 1, 2, 24) are open

collector NPN transistors capable of sinking 50 mA with a

minimum breakdown of 30 V. Interfacing into higher

voltage applications is easily accomplished with the circuits

shown in Figures 24 and 25.

The three totem pole bottom drive outputs (Pins 19, 20,

21) are particularly suited for direct drive of N−Channel

MOSFETs or NPN bipolar transistors (Figures 26, 27, 28

and 29). Each output is capable of sourcing and sinking up

to 100 mA. Power for the bottom drives is supplied from VC

(Pin 18). This separate supply input allows the designer

added flexibility in tailoring the drive voltage, independent

of VCC. A zener clamp should be connected to this input

when driving power MOSFETs in systems where VCC is

greater than 20 V so as to prevent rupture of the MOSFET

gates.

The control circuitry ground (Pin 16) and current sense

inverting input (Pin 15) must return on separate paths to the

central input source ground.

Thermal Shutdown

Internal thermal shutdown circuitry is provided to protect

the IC in the event the maximum junction temperature is

exceeded. When activated, typically at 170°C, the IC acts as

though the Output Enable was grounded.

tDLY [RDLY CDLY InǒVref –(I

IL enable RDLY)

Vth enable – (IIL enable RDLY)Ǔ

Figure 23. Timed Delayed Latched

Over Current Shutdown

REF

UVLO

Reset

POS

DEC

CDLY

25 μA

Load

Figure 24. High Voltage Interface with

NPN Power Transistors

T ransistor Q 1 is a common base stage used to level shift from VCC to the

high motor voltage, VM. The collector diode is required if VCC is present

while VM is low.

[RDLY CDLY Inǒ6.25 – (20 x 10–6 RDLY)

1.4 – (20 x 10–6 RDLY)Ǔ

Rotor

Position

Decoder

VCC

RDLY

MC33035, NCV33035

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Figure 25. High Voltage Interface with

N−Channel Power MOSFETs Figure 26. Current Waveform Spike Suppression

The addition of the RC filter will eliminate current−limit instability caused by th

leading edge spike on the current waveform. Resistor RS should be a low in

ductance type.

Load

Rotor

Position

Decoder

14 VM = 170 V

VCC = 12 V

MOC8204

Optocoupler

1N4744

1.0 k

4.7 k

1.0 M

VBoost

Brake Input

40 k

100 mV

Figure 27. MOSFET Drive Precautions Figure 28. Bipolar Transistor Drive

−

Base Charge

Removal

Series gate resistor Rg will dampen any high frequency oscillations caused

by the MOSFET input capacitance and any series wiring induction in the

gate−source circuit. Diode D is required if the negative current into the Bot-

tom Drive Outputs exceeds 50 mA.

The totem−pole output can furnish negative base current for enhanced tran-

sistor turn−off, with the addition of capacitor C.

Brake Input

D = 1N5819

40 k

100 mV

Brake Input

40 k

100 mV

MC33035, NCV33035

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Figure 29. Current Sensing Power MOSFETs Figure 30. High Voltage Boost Supply

SENSEFET

Virtually lossless current sensing can be achieved with the implementation of

SENSEFET power switches.

VPin9[

RS@Ipk @RDS(on)

rDM(on) )RS

Power Ground:

To Input Source Return

If: SENSEFET = MPT10N10M

RS = 200 Ω, 1/4 W

Then : VPin 9 ≈ 0.75 Ipk

16 Gnd

Control Circuitry Ground (Pin 16) and Current Sense Inverting Input (Pin 15)

must return on separate paths to the Central Input Source Ground.

100 mV

This circuit generates VBoost for Figure 25.

1.0/200 V

VBoost

1N5352A

MC1555

0.001 18 k

VM + 12

VCC = 12 V

VM = 170 V

* = MUR115

Boost Current (mA)

VM + 4.0 40

760

VM + 8.0

Boost Voltage (V)

Figure 31. Differential Input Speed Controller Figure 32. Controlled Acceleration/Deceleration

REF

PWM

VPin13 +VAǒR3)R4

R1)R2ǓR2

*ǒR4

VBǓResistor R1 with capacitor C sets the acceleration time constant while R2

controls the deceleration. The values of R1 and R2 should be at least te

times greater than the speed set potentiometer to minimize time constan

variations with different speed settings.

PWM

Enable

Increase

Speed

REF

25 μA

MC33035, NCV33035

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PWM

The SN74LS145 is an open collector BCD to One of Ten decoder. When con-

nected as shown, input codes 0000 through 1001 steps the PWM in incre-

ments of approximately 10% from 0 to 90% on−time. Input codes 1010

through 1111 will produce 100% on−time or full motor speed.

Figure 33. Digital Speed Controller Figure 34. Closed Loop Speed Control

VCC

Gnd Q0

240.4 k

BCD

Inputs

100 k

51.3 k

63.6 k

77.6 k

92.3 k

108 k

9126 k

145 k

166 k

5.0 V

SN74LS145

REF

12 25 μA

REF

PWM

The rotor position sensors can be used as a tachometer. By differentiatin

the positive−going edges and then integrating them over time, a voltag

proportional t o speed can be generated. The error amp compares this vo

lt-

age to that of the speed set to control the PWM.

0.22

1.0 M

0.1

100 k

0.01

10 k

1.0 M

To Sensor

Input (Pin 4) 25 μA

REF

PWM

This circuit can control the speed of a cooling fan proportional to the dif ference

between the sensor and set temperatures. The control loop is closed as the

forced air cools the NTC thermistor. For controlled heating applications, ex-

change the positions of R1 and R2.

Figure 35. Closed Loop Temperature Control

VB+

Vref

ǒR5

)1

R3§§ R5øR

VPin3+VrefǒR3)R4

R1)R2ǓR2

*ǒR4

VBǓ

25 μA

MC33035, NCV33035

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SYSTEM APPLICATIONS

Three Phase Motor Commutation

The three phase application shown in Figure 36 is a

full−featured open loop motor controller with full wave, six

step drive. The upper power switch transistors are

Darlingtons while the lower devices are power MOSFETs.

Each of these devices contains an internal parasitic catch

diode that is used to return the stator inductive energy back

to the power supply. The outputs are capable of driving a

delta or wye connected stator, and a grounded neutral wye

if split supplies are used. At any given rotor position, only

one top and one bottom power switch (of different totem

poles) is enabled. This configuration switches both ends of

the stator winding from supply to ground which causes the

current flow to be bidirectional or full wave. A leading edge

spike is usually present on the current waveform and can

cause a current−limit instability. The spike can be eliminated

by adding an RC filter in series with the Current Sense Input.

Using a low inductance type resistor for RS will also aid in

spike reduction. Care must be taken in the selection of the

bottom power switch transistors so that the current during

braking does not exceed the device rating. During braking,

the peak current generated is limited only by the series

resistance of the conducting bottom switch and winding.

Ipeak +VM)EMF

Rswitch )Rwinding

If the motor is running at maximum speed with no load, the

generated back EMF can be as high as the supply voltage,

and at the onset of braking, the peak current may approach

twice the motor stall current. Figure 37 shows the

commutation waveforms over two electrical cycles. The

first cycle (0° to 360°) depicts motor operation at full speed

while the second cycle (360° to 720°) shows a reduced speed

with about 50% pulse width modulation. The current

waveforms reflect a constant torque load and are shown

synchronous to the commutation frequency for clarity.

Figure 36. Three Phase, Six Step, Full Wave Motor Controller

Motor

Enable

Oscillator

Error Amp

PWM

Thermal

Shutdown

Reference

Regulator

Lockout

Undervoltage

Fwd/Rev

Faster

Speed

Set

Rotor

Position

Decoder

60°/120°

Brake

Fault

Ind.

Gnd 16 23

25 μA

ILimit

MC33035, NCV33035

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Figure 37. Three Phase, Six Step, Full Wave Commutation Waveforms

Rotor Electrical Position (Degrees)

100 000001

011111110

100

000001011111110

720660600540

480420360300240180120600

Code

Sensor Inputs

60°/120°

Select Pin

Open

Sensor Inputs

60°/120°

Select Pin

Grounded

Q2 + Q6

Q2 + Q4Q3 + Q4Q3 + Q5Q1 + Q5Q1 + Q6

Bottom Drive

Outputs

Q2 + Q6Q2 + Q4Q3 + Q4Q3 + Q5

Motor Drive

Current B

Fwd/Rev = 1

−

Conducting

Power Switch

Transistors Q1 + Q5

Top Drive

Outputs

Q1 + Q6

−

100 110 001011 001011110100010 010 101101

Reduced Speed ( ≈ 50% PWM)Full Speed (No PWM)

MC33035, NCV33035

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Figure 38 shows a three phase, three step, half wave motor

controller. This configuration is ideally suited for

automotive and other low voltage applications since there is

only one power switch voltage drop in series with a given

stator winding. Current flow is unidirectional or half wave

because only one end of each winding is switched.

Continuous braking with the typical half wave arrangement

presents a motor overheating problem since stator current is

limited only by the winding resistance. This is due to the lack

of upper power switch transistors, as in the full wave circuit,

used to disconnect the windings from the supply voltage

VM. A unique solution is to provide braking until the motor

stops and then turn off the bottom drives. This can be

accomplished b y using the Fault Output in conjunction with

the Output Enable as an over current timer. Components

RDLY and CDLY are selected to give the motor sufficient time

to stop before latching the Output Enable and the top drive

AND gates low. When enabling the motor , the brake switch

is closed and the PNP transistor (along with resistors R1 and

RDLY) are used to reset the latch by discharging CDLY. The

stator flyback voltage is clamped by a single zener and three

diodes.

Figure 38. Three Phase, Three Step, Half Wave Motor Controller

Motor

Oscillator

Gnd

ILimit

Error Amp

PWM

Thermal

Shutdown

Reference

Regulator

Lockout

Undervoltage

Fwd/Rev

Faster

60°/120°

Speed

Set

Rotor

Position

Decoder

Brake

CDLY

RDLY

25 μA

MC33035, NCV33035

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Three Phase Closed Loop Controller

The MC33035, by itself, is only capable of open loop

motor speed control. For closed loop motor speed control,

the MC33035 requires an input voltage proportional to the

motor speed. Traditionally, this has been accomplished by

means o f a tachometer to generate the motor speed feedback

voltage. Figure 39 shows an application whereby an

MC33039, powered from the 6.25 V reference (Pin 8) of the

MC33035, i s used to generate the required feedback voltage

without the need of a costly tachometer. The same Hall

sensor signals used by the MC33035 for rotor position

decoding are utilized by the MC33039. Every positive or

negative going transition of the Hall sensor signals on any

of the sensor lines causes the MC33039 to produce an output

pulse of defined amplitude and time duration, as determined

by the external resistor R1 and capacitor C1. The output train

of pulses at Pin 5 of the MC33039 are integrated by the error

amplifier of the MC33035 configured as an integrator to

produce a DC voltage level which is proportional to the

motor speed. This speed proportional voltage establishes the

PWM reference level at Pin 13 of the MC33035 motor

controller and closes the feedback loop. The MC33035

outputs drive a TMOS power MOSFET 3−phase bridge.

High currents can be expected during conditions of start−up,

breaking, and change of direction of the motor.

The system shown in Figure 39 is designed for a motor

having 120/240 degrees Hall sensor electrical phasing. The

system can easily be modified to accommodate 60/300

degree Hall sensor electrical phasing by removing the

jumper (J2) at Pin 22 of the MC33035.

Figure 39. Closed Loop Brushless DC Motor Control

Using The MC33035 and MC33039

Motor

TP2

0.05/1.0 W

0.1 33

TP1

1.0 k

VM (18 to 30 V)

1000

0.1

1.1 k

Close Loop

0.1

1.0 M

0.01

Speed

Faster

4.7 k

F/R

Brake

1.0 k

470

1N5819

1.1 k 1.1 k

1.0 k

MC33035

MC33039

1.0 M

750 pF

10 k

100 k

100

5.1 k

Enable J1330

47 μF

1N5355B

18 V

2.2 k

0.1

1N4148

Latch On

Fault

Reset

2.2 k

MC33035, NCV33035

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Sensor Phasing Comparison

There are four conventions used to establish the relative

phasing of the sensor signals in three phase motors. With six

step drive, an input signal change must occur every 60

electrical degrees; however, the relative signal phasing is

dependent upon the mechanical sensor placement. A

comparison o f the conventions in electrical degrees is shown

in Figure 40. From the sensor phasing table in Figure 41,

note that the order of input codes for 60° phasing is the

reverse o f 3 0 0 °. This means the MC33035, when configured

for 60° sensor electrical phasing, will operate a motor with

either 60° or 300°sensor electrical phasing, but resulting in

opposite directions of rotation. The same is true for the part

when it is configured for 120°sensor electrical phasing; the

motor will operate equally, but will result in opposite

directions of rotation for 120°for 240° conventions.

Figure 40. Sensor Phasing Comparison

Rotor Electrical Position (Degrees)

300°

240°

720660600540480420360300240180120600

120°

60°

Sensor Electrical Phasing

Sensor Electrical Phasing (Degrees)

60°120°240°300°

SASBSCSASBSCSASBSCSASBSC

100101110111

110100100110

1111101011 0 0

011010001000

001011011001

000001010011

Figure 41. Sensor Phasing Table

In this data sheet, the rotor position is always given in

electrical degrees since the mechanical position is a function

of the number of rotating magnetic poles. The relationship

between the electrical and mechanical position is:

Electrical Degrees +Mechanical Degreesǒ#Rotor Poles

2Ǔ

An increase in the number of magnetic poles causes more

electrical revolutions for a given mechanical revolution.

General purpose three phase motors typically contain a four

pole rotor which yields two electrical revolutions for one

mechanical.

Two and Four Phase Motor Commutation

The MC33035 is also capable of providing a four step

output that can be used to drive two or four phase motors.

The truth table in Figure 42 shows that by connecting sensor

inputs SB and SC together, it is possible to truncate the

number of drive output states from six to four. The output

power switches are connected to BT, CT, BB, and CB.

Figure 43 shows a four phase, four step, full wave motor

control application. Power switch transistors Q1 through Q8

are Darlington type, each with an internal parasitic catch

diode. With four step drive, only two rotor position sensors

spaced at 90 electrical degrees are required. The

commutation waveforms are shown in Figure 44.

Figure 45 shows a four phase, four step, half wave motor

controller. I t has the same features as the circuit in Figure 38,

except for the deletion of speed control and braking.

MC33035 (60°/120° Select Pin Open)

Inputs Outputs

Sensor Electrical

Spacing* = 90°

Top Drives Bottom Drives

SASBF/R BTCTBBCB

*With MC33035 sensor input SB connected to SC.

Figure 42. Two and Four Phase, Four Step,

Commutation Truth Table

MC33035, NCV33035

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Enable

Fwd/Rev

Lockout

Rotor

Undervoltage

Motor

Reference

Thermal

Oscillator

Gnd 16

CRS

Position

Decoder

Shutdown

Regulator

Error Amp

PWM

ILimit

25 A

Fault

Ind.

Figure 43. Four Phase, Four Step, Full Wave Motor Controller

MC33035, NCV33035

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Conducting

Power Switch

Transistors

Code

Q3 + Q5

Rotor Electrical Position (Degrees)

Fwd/Rev = 1

−

Q2 + Q8

Q1 + Q7

Q4 + Q6

Q3 + Q5

Q2 + Q8

Q1 + Q7

Q4 + Q6

0001111000011010

Motor Drive

Current

Bottom Drive

Outputs

Top Drive

Outputs

Sensor Inputs

60°/120°

Select Pin

Open

180 270 360 450 540 630 720090

Figure 44. Four Phase, Four Step, Full Wave Motor Controller

Full Speed (No PWM)

MC33035, NCV33035

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Motor

Enable

Fwd/Rev

Lockout

Rotor

Undervoltage

Reference

Thermal

Oscillator

Gnd 16

Position

Decoder

Shutdown

Regulator

Error Amp

PWM

ILimit

Brake

25 A

Fault

Ind.

Figure 45. Four Phase, Four Step, Half Wave Motor Controller

MC33035, NCV33035

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Brush Motor Control

Though the MC33035 was designed to control brushless

DC motors, it may also be used to control DC brush type

motors. Figure 46 shows an application of the MC33035

driving a MOSFET H−bridge affording minimal parts count

to operate a brush−type motor. Key to the operation is the

input sensor code [100] which produces a top−left (Q1) and

a bottom−right (Q3) drive when the controller’s

forward/reverse pin i s a t l ogic [ 1]; t op−right ( Q4), b ottom−left

(Q2) drive is realized when the Forward/Reverse pin is at

logic [0]. This code supports the requirements necessary for

H−bridge drive accomplishing both direction and speed

control.

The controller functions in a normal manner with a pulse

width modulated frequency of approximately 25 kHz.

Motor speed is controlled by adjusting the voltage presented

to the noninverting input of the error amplifier establishing

the PWM’s slice or reference level. Cycle−by−cycle current

limiting of the motor current is accomplished by sensing the

voltage (100 mV) across the RS resistor to ground of the

H−bridge motor current. The over current sense circuit

makes i t possible to reverse the direction of the motor, using

the normal forward/reverse switch, on the fly and not have

to completely stop before reversing.

LAYOUT CONSIDERATIONS

Do not attempt to construct any of the brushless motor

control circuits on wire−wrap or plug−in prototype

boards. High frequency printed circuit layout techniques

are imperative to prevent pulse jitter. This is usually caused

by excessive noise pick−up imposed on the current sense or

error amp inputs. The printed circuit layout should contain

a ground plane with low current signal and high drive and

output bu ffer grounds returning on separate paths back to the

power supply input filter capacitor VM. Ceramic bypass

capacitors (0.1 μF) connected close to the integrated circuit

at VCC, VC, Vref and the error amp noninverting input may

be required depending upon circuit layout. This provides a

low impedance path for filtering any high frequency noise.

All high current loops should be kept as short as possible

using heavy copper runs to minimize radiated EMI.

MC33035, NCV33035

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0.005

10 k

Oscillator

Gnd

ILimit

Error Amp

PWM

Thermal

Shutdown

Reference

Regulator

Lockout

Undervoltage

+12 V

Fwd/Rev

Faster

Rotor

Position

Decoder

Brake

25 μA

Figure 46. H−Bridge Brush−Type Controller

1.0 k

0.001

DC Brush

Motor M

+12 V

1.0 k

Q1*

Q2*

Q4*

Q3*

Enable

10 k

Fault

Ind.

20 k

MC33035, NCV33035

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ORDERING INFORMATION

Device Operating Temperature Range Package Shipping†

MC33035DW

TA = −40°C to +85°C

SO−24L 30 Units / Rail

MC33035DWG SO−24L

(Pb−Free) 30 Units / Rail

MC33035DWR2 SO−24L 1000 Tape & Reel

MC33035DWR2G SO−24L

(Pb−Free) 1000 Tape & Reel

MC33035P Plastic DIP 15 Units / Tube

MC33035PG Plastic DIP

(Pb−Free) 15 Units / Tube

NCV33035DWR2* TA = −40°C to +125°CSO−24L 1000 Tape & Reel

NCV33035DWR2G* SO−24L

(Pb−Free) 1000 Tape & Reel

†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging

Specification Brochure, BRD8011/D.

*NCV33035: T low = −40C, Thigh = +125C. Guaranteed by design. NCV prefix is for automotive and other applications requiring site and change

control.

PDIP−24

P SUFFIX

CASE 724

MC33035P

AWLYYWWG

MARKING DIAGRAMS

A = Assembly Location

WL = Wafer Lot

YY = Year

WW = Work Week

G = Pb−Free Package

MC33035DW

AWLYYWWG

SO−24

DW SUFFIX

CASE 751E

NCV33035DW

AWLYYWWG

MC33035, NCV33035

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PACKAGE DIMENSIONS

P SUFFIX

PLASTIC PACKAGE

CASE 724−03

ISSUE D

MIN MINMAX MAX

INCHES MILLIMETERS

DIM

1.265

0.270

0.175

0.020

0.060

0.012

0.140

15°

0.040

0.050 BSC

0.100 BSC

0.300 BSC

1.27 BSC

2.54 BSC

7.62 BSC

31.25

6.35

3.69

0.38

1.02

0.18

2.80

0°

0.51

32.13

6.85

4.44

0.51

1.52

0.30

3.55

15°

1.01

1.230

0.250

0.145

0.015

0.040

0.007

0.110

0°

0.020

NOTES:

1. CHAMFERED CONTOUR OPTIONAL.

2. DIMENSION L TO CENTER OF LEADS WHEN

FORMED PARALLEL.

3. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

4. CONTROLLING DIMENSION: INCH.

112

1324

-A-

-B-

-T-

SEATING

PLANE

GEF

D 24 PL

J 24 PL

NOTE 1

0.25 (0.010) T A

M M

0.25 (0.010) T B

M M

DW SUFFIX

PLASTIC PACKAGE

CASE 751E−04

(SO−24L)

ISSUE E

0.010 (0.25) A B

MS S MIN MINMAX MAX

MILLIMETERS INCHES

DIM

15.25

7.40

2.35

0.35

0.41

0.23

0.13

0°

10.05

0.25

15.54

7.60

2.65

0.49

0.90

0.32

0.29

8°

10.55

0.75

0.601

0.292

0.093

0.014

0.016

0.009

0.005

0°

0.395

0.010

0.612

0.299

0.104

0.019

0.035

0.013

0.011

8°

0.415

0.029

1.27 BSC 0.050 BSC

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

2. CONTROLLING DIMENSION: MILLIMETER.

3. DIMENSIONS A AND B DO NOT INCLUDE

MOLD PROTRUSION.

4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)

PER SIDE.

5. DIMENSION D DOES NOT INCLUDE DAMBAR

PROTRUSION. ALLOWABLE DAMBAR

PROTRUSION SHALL BE 0.13 (0.005) TOTAL IN

EXCESS OF D DIMENSION AT MAXIMUM

MATERIAL CONDITION.

-A-

-B-

112

24 13

-T-

SEATING

PLANE

R X 45°

G 22 PL

P 12 PL

0.010 (0.25) B

M M

D 24 PL

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