NCV33035 データシートの表示（PDF） - ON Semiconductor

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NCV33035

Brushless DC Motor Controller

ON Semiconductor 

MC33035, NCV33035

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 of 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 of 300°. 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.

Rotor Electrical Position (Degrees)

0 60 120 180 240 300 360 420 480 540 600 660 720

SA

60° SB

SC

SA

120° SB

SC

SA

240° SB

SC

SA

300° SB

SC

Figure 40. Sensor Phasing Comparison

Sensor Electrical Phasing (Degrees)

60°

120°

240°

300°

SA SB SC SA SB SC SA SB SC SA SB SC

100101110111

110100100110

111110101100

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:

ǒ Ǔ Electrical Degrees + Mechanical Degrees

#Rotor Poles

2

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. It 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°

SA

SB

F/R

1

0

1

1

1

1

0

1

1

0

0

1

Top Drives Bottom Drives

BT

CT

BB

CB

1

1

0

1

0

1

0

0

1

0

0

0

1

1

1

0

1

0

0

1

0

0

0

1

1

0

1

1

1

0

0

1

0

1

1

0

1

0

0

0

0

1

0

0

*With MC33035 sensor input SB connected to SC.

Figure 42. Two and Four Phase, Four Step,

Commutation Truth Table

http://onsemi.com

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