Datasheet UC1633, UC2633, UC3633 Datasheet (UNITRODE)

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Phase Locked Frequency Controller

UC1633
UC2633
UC3633

FEATURES

• Precision Phase Locked Frequency
Control System

• Crystal Oscillator

• Programmable Reference Frequency

Dividers

• Phase Detector with Absolute Frequency
Steering

• Digital Lock Indicator

• Double Edge Option on the Frequency

Feedback Sensing Amplifier

• Two High Current Op-Amps

• 5V Reference Output

DESCRIPTION

The UC1633 family of integrated circuits was designed for use in phase
locked frequency control loops. While optimized for precision speed
control of DC m ot ors, t hes e devices ar e u niversa l en ough for most ap­plications that require phase locked control. A precise reference fre­quency c an be generated us ing the device’s high frequency oscillator
and programma ble frequency dividers. The oscillator operates using a
broad range of crystals, or, can function as a buffer stage to an external
frequency source.

The phase detector on these integrated circuits compares the refer­ence freque ncy with a f requenc y/phase feedback signal. In the case of
a motor, feedback is obtained at a hall ou tput of ot her speed detection
device. This signal is buffered by a sense ampilfier that squares up the
signal as it goes into the digital phase detector. The phase detector re­sponds propor tionally to the phase error between the reference and the
sense amplifier output. This phase detector includes absolute fre­quency steering to provide maximum drive signals when any frequency
error exists. This feature allows optimum start-up and lock times to be
realized.

Two op-amps are included that can be configured to provide necessary
loop filtering. The outputs of the op-amps will source or sink in excess
of 16mA, so they can provide a low impedence control signal to driving
circuits.

BLOCK DIAGRAM

Additional featur es i nc l ud e a do uble edge option on the sense amplifier
that can be use d to double the loop reference frequency for increased
loop bandwidths. A digital lock signal is provided that indicates when
there is zero fr equen cy erro r, and a 5V reference output allows DC op­erating levels to be accurately set.

4/97

1

ABSOLUTE MAXIMUM RATINGS

Input Supply Voltage (+VIN) . . . . . . . . . . . . . . . . . . . . . . . . +20V

Reference Output Current . . . . . . . . . . . . . . . . . . . . . . . . -30mA

Op-Amp Output Currents . . . . . . . . . . . . . . . . . . . . . . . . ±30mA

Op-Amp Input Voltages . . . . . . . . . . . . . . . . . . . . . -.3V to +20V

Phase Detector Output Current . . . . . . . . . . . . . . . . . . . ±10mA

Lock Indicator Output Current . . . . . . . . . . . . . . . . . . . . +15mA

Lock Indicator Output Voltage . . . . . . . . . . . . . . . . . . . . . . +20V

Divide Select Input Voltages . . . . . . . . . . . . . . . . . -.3V to +10V

Double Edge Disable Input Voltage . . . . . . . . . . . . -.3V to +10V

Oscillator Input Voltage . . . . . . . . . . . . . . . . . . . . . . -.3V to +5V

Sense Amplifier Input Voltage . . . . . . . . . . . . . . . . .3V to +20V

Power Dissipation at TA = 25°C (Note 2 . . . . . . . . . . . 1000mW

Power dissipation at TC = 25°C (Note 2) . . . . . . . . . . . 2000mW

Operating Junction Temperature . . . . . . . . . . . -55°C to +150°C

Storage Temperature . . . . . . . . . . . . . . . . . . . . -65°C to +150°C

Lead Temperature (Soldering, 10 Seconds) . . . . . . . . . . 300°C

DIL-16 (TOP VIEW)
J or N Package

UC1633
UC2633
UC3633

Note1: V oltages are referenced to ground, (Pin 16). Currents
are positive into, negative out of, the specified terminals.
Note 2: Consult Packaging Section of Databook for thermal limi­tations and considerations of package.

CONNECTION DIAGRAMS

PLCC-20 (T OP VIEW)
Q Package

PACKAGE PIN FUNCTION

FUNCTION PIN

N/C
Div 4/5 Input
Div 2/4/8 Input
Lock Indicator Output
Phase Detector Output
N/C
Dbl Edge Disable Input
Sense Amp Input
5V Ref Output
Loop Amp Inv Input
N/C
Loop Amp Output
Aux Amp Non-Inv Input
Aux Amp Inv Input
Aux Amp Output
N/C
+V

IN

OSC Output
OSC Input
Ground

1

2
3
4
5
6
7
8

9
10
11
12
13
14
15
16
17
18
19
20

ELECTRICAL CHARACTERISTICS:

(Unless otherwise stated, these specifications apply for TA = 0°C to +70°C for the
UC3633, -25°C to +85°C for the UC2633, -55°C to +125°C for the UC1633, +VIN =
12V; TA=TJ.)

PARAMETER TEST CONDITIONS MIN. TYP. MAX. UNITS

Supply Current +VIN = 15V 20 28 mA

Reference

Output Voltage (V
Load Regulation I
Line Regulation +V
Short Circuit Current V

) 4.75 5.0 5.25 V

REF

= 0V to 7mA 5.0 20 mV

OUT

= 8V to 15V 2.0 20 mV

IN

= 0V 12 30 mA

OUT

Oscillator

DC Voltage Gain Oscillator Input to Oscillator Output 12 16 20 dB
Input DC Level (V
Input Impedance (Note 3) V

) Oscillator Input Pin Open, TJ = 25°C 1.15 1.3 1.45 V

IB

= VIB ±0.5V, TJ = 25°C 1.3 1.6 1.9 k

IN

Output DC Level Oscillator Input Pin Open, TJ = 25°C 1.2 1.4 1.6 V
Maximum Operating Frequency 10 MHz

Dividers

Maximum Input Frequency Input = 1VPP at Oscillator Input 10 MHz
Div. 4/5 Input Current Input = 5V (Div. by 4) 150 500

Input = 0V (Div. by 5) -5.0 0.0 5.0

Div. 4/5 Threshold 0.5 1.6 2.2 V

Note 3: These impedence levels will vary with TJ at about 1700ppm/°C

Ω

A

µ

A

µ

2

UC1633
UC2633
UC3633

ELECTRICAL
CHARACTERISTICS (cont.):

(Unless otherwise stated, these specifications apply for TA = 0°C to +70°C for t he UC3 633,

-25°C to +85°C for the UC2633, -55°C to +125°C for the UC1633, +VIN = 12V; TA=TJ.)

PARAMETER TEST CONDITIONS MIN. TYP. MAX. UNITS

Dividers (cont.)

Div. 2/4/8 Input Curre nt Input = 5V (Div. by 8) 150 500

Input = 0V (Div. by 2) -500 -150
Div. 2/4/8 Open Circui t Voltage Input Current = 0µA (Div. by 4) 1.5 2.5 3.5 V
Div. by 2 Threshold 0.20 0.8 V
Div. by 4 Threshold 1.5 3.5 V
Div. by 8 Threshold Volts Below V

REF

0.20 0.8 V

Sense Amplifier

Threshold Voltage Percent of V

REF

27 30 33 %
Threshold Hysteresis 10 mV
Input Bias Current Input = 1.5V -1.0 -0.2

Double Edge Disable Input

Input Current Input = 5V (Disabled) 150 500

Input = 0V (Enabled) -5.0 0.0 5.0

Threshold Voltage 0.5 1.6 2.2 v

Phase Detector

High Output Level Positive Phase/Freq. Error, Volts Below V

REF

0.2 0.5 V
Low Output Level Negative Phase/Freq. Error 0.2 0.5 V
Mid Output Level Zero Phase/Freq. Error, Percen t of V
High Level Maximum Source Current V
Low Level Maximum Sink Current V
Mid Level Outpu t Im pe da nc e (N ot e 3) I

= 4.3V 2.0 8.0 mA

OUT

= 0.7V 2.0 5.0 mA

OUT

= -200 to +200µA, TJ = 25°C 4.5 6.0 7.5 k

OUT

REF

47 50 53 %

Lock Indicator Output

Saturation Voltage Freq. Error, I
Leakage Current Zero Freq. Error, V

= 5mA 0.3 0.45 V

OUT

= 15V 0.1 1.0

OUT

Loop Amplifier

NON INV. Reference Voltage Percent of V

REF

47 50 53 %
Input Bias Current Input = 2.5V -0.8 -0.2
AVOL 60 75 dB
PSRR +V
Short Circuit Current Source, V

= 8V to 15V 70 100 dB

IN

= 0V 16 35 mA

OUT

Sink, V

= 5V 16 30 mA

OUT

Auxiliary Op-Amp

Input Offset Voltage V

= 2.5V 8 mV

CM

Input Bias Current VCM = 2.5V -0.8 -0.2
Input Offset Current V

= 2.5V .01 0.1

CM

AVOL 70 120 dB
PSRR +V

= 8V to 15V 70 100 dB

IN

CMRR VCM = 0V to 10V 70 100 dB
Short Circuit Current Source, V

Sink, V

= 0V 16 35 mA

OUT

= 5V 16 30 mA

OUT

Note 3: These impedence levels will vary with TJ at about 1700pp m/°C

A

µ

A

µ

A

µ

A

µ

A

µ

Ω

A

µ

A

µ

A

µ

A

µ

3

APPLICATION AND OPERATING INFORMATION

Determining the Oscillator Frequency

The frequency at the oscillator is deter mined by the de­sired RPM of the motor, the divide ratio selected, the
number of poles in the motor, and the state of the double
edge select pin.

f

(Hz) = (Divide Rati o) • (Motor RPM ) • (1/60 SEC/MIN) •

OSC

(No. of Rotor Poles/2) • (x 2 if Pin 5 Low)

Recommended Oscillator Configuration Using AT Cut Quartz Crystal

UC1633
UC2633
UC3633

The resulting referen c e f req uenc y appearing at the phase
detector inputs is equal to the oscillator frequency divided
by the selected divide ratio. If the double edge option is
used, (Pin 5 low), the f requency of the sense amplifier in­put signal is doubled by responding to both the rising and
falling edges of the input signal. Using this option, the loop
reference frequency can be doubled for a given motor
RPM.

External Reference Frequency Input

Method for Deriving Rotation Feedback Signal from Analog Hall Effect Device

*This signal may require filtering if chopped mode drive scheme is used.

4

APPLICATION AND OPERATION INFORMATION

Phase Detector Operation

The phase detector on these devices is a digital circuit
that responds to the rising edges of the detector’s two in­puts. The phase detector output has three states: a high,
5V state, a low, 0V state, and a middle, 2.5V state. In the
high and low states the output impedance of the detector
is low and the middle state output impedence is high, typi­cally 6.0kΩ. When there is any static fr equency difference
between the inputs, the detector output is fixed at its high
level if the +input (the sen se ampl ifie r signal) is greater in
frequency, and fixed at its low level if the -input (the refer­ence frequency signal) is greater in frequency.

When the frequencies of the two inputs to the detector
are equal, the phase detector switches between its middle
state and either the high or low st ates, d epending on the
relative phase of the two signals. If the +input is leading in
phase then, during each period of the input fr equency, the
detector output will be high for a time equal to the time dif­ference between the rising edges of the inputs, and will
be at its middle level for the remainder of the period. If the
phase relationship is reversed, then the detector will go
low for a time proportional to the phase difference of the
inputs. The resulting gain of the phase detector. kø, is

T ypical Phase Detector Output Waveforms

UC1633
UC2633
UC3633

5V/4π radians or about 0.4V/radian. The dynamic range of
the detector is ±2π radians.

The operation of the phase detector is illustrated in the
figures below. The upper figure shows typical voltage
waveforms seen at the detector output for leading and
lagging phase conditions. The lower figure is a state dia­gram of the pha se det ect or l ogic. In this figure, the circles
represent the 10 possible states of the logic, and the con­necting arrows represent the transition events/paths to
and from these states. Transition arrows that have a clock­wise rotation ar e the result of a rising edge on the +input,
and conversely, those with counter-clockwise rotation are
tied to the rising edge of the -input signal.

The normal operational states of the logic are 6 and 7 for
positive phase er ror, 1 and 2 for a negative phase error.
States 8 and 9 occur during positive frequency error, 3
and 4 during negative frequency error. States 5 and 10
occur only as the inputs cross over from the frequency er­ror to a normal phase error only condition. The lev el of the
phase detector output is determined by the logic state as
defined in th e st a te d ia gram figure. The lock indicator out­put is high, off, when the detector is in states 1, 2, 6, or 7.

Phase Detector State Diagram

5

APPLICATION AND OPERATION INFORMATION

Suggested Loop Filter Configuration

UC1633
UC2633
UC3633

* The static phase error of the loop is easily adjusted by
adding resistor, R
R

is determined by:

4

, as shown. To lock at zero phase error

4

•

2.5V

=

4

R

| ∆

3

R

|

OUT

V

Reference Filter Configuration

ν

OUT

ν

3

R

) =

(

s

1

IN

R

•

1 +
1 +

s

z

⁄

ω

s

p

⁄

ω

1

=

ω

p

=

ω

z

Where: |∆V
and V

R

(R

2

C

1

1

1

+ R

)

2

1

C

OUT

| = |V

OUT

- 2.5V|

OUT

= DC Operating Voltage At

Loop Amplifier Output During Phase Lock

If: (V
(V

- 2.5) > 0, R4 Goes to 0V

OUT

- 2.5) < 0, R4 Goes to 5.0V

OUT

OUT

ν

) =

(

s

IN

ν

s 2

+

1

1

2

ζ

s

+

N

ω

2

N

ω

Reference Filter Design Aid - Gain Response

=

ω

N

ζ

=

2

Note: with R1 = R2,

1

√

1R2C1C2

R

1

1

=

√

2

Q

C
C

2
1

ζ =

1

+

R

√

R1R

√

2

R

2

2

C

1

C

Reference Filter Design Aid - Phase Response

6

APPLICATION AND OPERATION INFORMATION

Design Example

UC1633
UC2633
UC3633

Bode Plots - Design Example Open Loop Response

1.)

KLF(s) • KRF(s)

•

2.*)

•

φ

N

K

s

•

PD

T

K

G

2

•

J

3.) Combined Overall Open Loop Response

Where:

K

(s) = Loop Filter Response

LF

K

(s) = Reference Filter Response

RF

N = 4 (Using Double Edge Sensing With 4 Pole

Motor)
Kφ = Phase Detector Gain (.4V/RAD)
G

= Power Stage Transductance (1A/V)

PD

K

= Motor Torque Constant (.022NM/A)

T

J = Motor Moment of Inertia (.0015NM/A - SEC

2

)

s = 2πjf

*Note: For a current mode driver the electrical time constant, LM / RM, of the motor does n ot en te r in to the small signal res po nse.
If a voltage mode drive scheme is used, then the asymptote, plotted as

L

• K φ

N

2 • J •

s

•

K

•

PD

R

M

T

K

if: R

>

K

M

M

T

√

and,

J

above, can be approximated by:

2

2

K

T

2π • J •

< f <

R

M

2π

R

M

L

•

M

Here: KPD = V oltage gain of Driver Stage

UNITRODE CORPORATION
7 CONTINENTAL BLVD. • MERRIMACK, NH 03054
TEL. (603) 424-2410 • FAX (603) 424-3460

= Motor Win di ng Resistance

R

M

LM = Motor Wind in g Inductance

7

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