UC384XAM_技术文档

UC184xA / 284xA / 384xA

CURRENT

MODE PWM CONTROLLER

P

R O D U C T I O N D A T A S H E E T

T

H E

I

N F I N I T E

P

O W E R O F

I N N O V A T I O N

KEY FEATURES

DESCRIPTION

The UC184xA family of control ICs provides externally programmable oscillator to set

all the necessary features to implement off-line frequency and maximum duty cycle. The

fixed-frequency, current-mode switching power undervoltage lock-out is designed to operate with

LOW START-UP CURRENT.

(0.5mA max.)

TRIMMED OSCILLATOR

DISCHARGE CURRENT. (See

Product Highlight)

OPTIMIZED FOR OFF-LINE

AND DC-TO-DC

CONVERTERS.

AUTOMATIC FEED FORWARD

COMPENSATION.

PULSE-BY-PULSE CURRENT

LIMITING.

ENHANCED LOAD RESPONSE

CHARACTERISTICS.

UNDER-VOLTAGE LOCKOUT

WITH HYSTERESIS.

DOUBLE PULSE

SUPPRESSION.

HIGH-CURRENT TOTEM POLE

OUTPUT.

INTERNALLY TRIMMED

BANDGAP REFERENCE.

500KHz OPERATION.

LOW RO ERROR AMPLIFIER.

supplies with

a

minimum of external 250µA typ. start-up current, allowing an efficient

components. The current mode architecture bootstrap supply voltage design. Available

demonstrates improved load regulation, pulse- options for this family of products, such as start-

by-pulse current limiting and inherent protection up voltage hysteresis and duty cycle, are

of the power supply output switch. The IC summarized below in the Available Options

includes: A bandgap reference trimmed to ±1% section. The UC184xA family of control ICs is

accuracy, an error amplifier, a current sense also available in 14-pin SOIC package which

comparator with internal clamp to 1V, a high makes the Power Output Stage Collector and

current totem pole output stage for fast Ground pins available.

switching of power MOSFET's, and an

IMPORTANT: For the most current data, consult MICROSEMI’s website: http://www.microsemi.com

PRODUCT HIGHLIGHT

COMPARISON OF UC384

XA

VS. SG384

X

D

ISCHARGE URRENT

C

UC384xA

SG384x

Min. Limit

SG384x

Max. Limit

T =25 C

A

KEY FEATURES

ECONOMICAL OFF-LINE

FLYBACK OR FORWARD

CONVERTERS.

DC-DC BUCK OR BOOST

CONVERTERS.

LOW COST DC MOTOR

CONTROL.

7.5

7.8

-3s

8.3

Mean

8.8

+3s

9.3

Available Options

Start-Up

Max. Duty

Cycle

Part#

Hysteresis

Voltage

UCx842A

UCx843A

UCx844A

UCx845A

16V

8.4V

16V

6V

0.8V

6V

<100%

<50%

Discharge Current Distribution - mA

8.4A

0.8V

<50%

PACKAGE ORDER INFO

Plastic DIP

8-Pin

Plastic SOIC

8-Pin

Plastic SOIC

14-Pin

Ceramic DIP

8-Pin

M

DM

D

Y

T_A(°C)

RoHS Compliant / Pb-free

Transition DC: 0503

RoHS Compliant / Pb-free Transition DC: 0440

0 to 70

-40 to +85

-55 to 125

UC384xAM

UC284xAM

-

UC384xADM

UC284xADm

-

UC384xAD

UC284xAD

-

UC284xAY

UC184xAY

Note: Available in Tape & Reel. Append the letters “TR” to the part number. (i.e. UC3842ADM-TR)

L

I N

F

I N I T Y

M

I C R O E L E C T R O N I C S

I N C .

Rev. 1.2a,2005-03-09

1

11861 WESTERN

A

VENUE, GARDEN GROVE, CA. 92841, 714-898-8121, FAX: 714-893-2570

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

PACKAGE PIN OUTS

ABSOLUTE MAXIMUM RATINGS (Note 1)

Supply Voltage (Low Impedance Source) (V_CC) ......................................................... 30V

Supply Voltage (I_CC< 30mA).......................................................................... Self Limiting

Output Current............................................................................................................. ±1A

Output Energy (Capacitive Load)................................................................................. 5µJ

Analog Inputs (V_FB& I_SENSE) ........................................................................ -0.3V to +6.3V

Error Amp Output Sink Current ............................................................................... 10mA

Power Dissipation at T_A= 25°C (M Package).............................................................. 1W

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

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

Peak Package Solder Reflow Temp. (40 second max. exposure)..........................................260°C (+0, -5)

COMP

V_FB

I_SENSE

R_T/C_T

1

2

3

4

8

7

6

5

V_REF

V_CC

OUTPUT

GND

M & Y PACKAGE

(Top View)

1

2

3

4

8

7

6

5

COMP

V_FB

I_SENSE

R_T/C_T

V_REF

V_CC

OUTPUT

GND

Note 1. Exceeding these ratings could cause damage to the device. All voltages are with respect

to Ground. Currents are positive into, negative out of the specified terminal. Pin

numbers refer to DIL packages only.

DM PACKAGE

(Top View)

THERMAL DATA

M PACKAGE:

THERMAL RESISTANCE-JUNCTION TO AMBIENT, θ_JA

DM PACKAGE:

95°C/W

165°C/W

120°C/W

130°C/W

1

2

3

4

5

6

7

14

13

12

11

10

9

COMP

N.C.

V_FB

N.C.

I_SENSE

N.C.

R_T/C_T

V_REF

N.C.

V_CC

V_C

OUTPUT

GND

PWR GND

THERMAL RESISTANCE-JUNCTION TO AMBIENT, θ_JA

D PACKAGE:

THERMAL RESISTANCE-JUNCTION TO AMBIENT, θ_JA

Y PACKAGE:

8

D PACKAGE

(Top View)

THERMAL RESISTANCE-JUNCTION TO AMBIENT, θ_JA

RoHS / Pb-free 100% Matte Tin Lead Finish

Junction Temperature Calculation: T_J= T_A+ (P_Dx θ_JA).

The θ numbers are guidelines for the thermal performance of the device/pc-board system.

All of^Jt^Ahe above assume no ambient airflow

Rev. 1.2a 10/25

2

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

ELECTRICAL CHARACTERISTICS

(Unless otherwise specified, these specifications apply over the operating ambient temperatures for UC384xA with 0°C ≤ T_A≤ 70°C, UC284xA with -40°C ≤ T_A≤ 85°C,

UC184xA with -55°C ≤ T_A≤ 125°C; V_CC=15V; R_T=10K; C_T=3.3nF. Low duty cycle pulse testing techniques are used which maintains junction and case temperatures equal

to the ambient temperature.)

UC184xA/284xA

Min. Typ. Max. Min. Typ. Max.

UC384xA

Parameter

Symbol

Test Conditions

Units

Reference Section

Output Voltage

V_REF

T_J= 25°C, I_L= 1mA

4.95 5.00 5.05 4.90 5.00 5.10

V

Line Regulation

12 ≤ V_IN≤ 25V

1 ≤ I_O≤ 20mA

6

20

25

6

20

25

mV

Load Regulation

0.2 0.4

5.1 4.82

0.2 0.4 mV/°C

Temperature Stability (Note 2 & 7)

Total Output Variation

Output Noise Voltage (Note 2)

Long Term Stability (Note 2)

Output Short Circuit Current

Oscillator Section

4.9

5.18

V

Over Line, Load, and Temperature

10Hz ≤ f ≤ 10kHz, T_J= 25°C

T_A= 125°C, t = 1000hrs

50

5

50

5

µV

mV

mA

V_N

I_SC

25

-30 -100 -180 -30 -100 -180

Initial Accuracy (Note 6)

Voltage Stability

T_J= 25°C

12 ≤ V_CC≤ 25V

47

52

0.2

5

57

1

47

52

0.2

5

57

1

kHz

%

Temperature Stability (Note 2)

Amplitude (Note 2)

Discharge Current

T_MIN≤ T_A≤ T_MAX

%

V

mA

1.7

7.8 8.3 8.8 7.8 8.3 8.8

7.5 8.8 7.6 8.8

T_J= 25°C, V_{PIN 4}= 2V

V_{PIN 4}= 2V, T_MIN≤ T_A≤ T_MAX

Error Amp Section

Input Voltage

Input Bias Current

V_{PIN 1}= 2.5V

2.45 2.50 2.55 2.42 2.50 2.58

V

µA

dB

MHz

dB

mA

V

I_B

-0.3

90

1

-1

-0.3

90

1

-2

Open Loop Gain

A_VOL

2 ≤ V_O≤ 4V

65

0.7

60

2

65

0.7

60

2

Unity Gain Bandwidth (Note 2)

Power Supply Rejection Ratio (Note 3)

Output Sink Current

Output Source Current

Output Voltage High Level

Output Voltage Low Level

Current Sense Section

UGBW T_j= 25°C

PSRR

I_OL

I_OH

12 ≤ V_CC≤ 25V

70

6

70

6

V_{PIN 2}= 2.7V, V_{PIN 1}= 1.1V

V_{PIN 2}= 2.3V, V_{PIN 1}= 5V

-0.5 -0.8

5

6

5

6

V_OH

V_OL

V_{PIN 2}= 2.3V, R_L= 15K to ground

V_{PIN 2}= 2.7V, R_L= 15K to V_REF

0.7 1.1

V

Gain (Note 3 & 4)

A_VOL

2.85

0.9

3

1

70

-2

3.15 2.85

1.1 0.9

3

1

70

-2

3.15

1.1

V/V

V

dB

µA

ns

Maximum Input Signal (Note 3)

Power Supply Rejection Ratio (Note 3)

Input Bias Current

V_{PIN 1}= 5V

PSRR

I_B

12 ≤ V_CC≤ 25V

-10

150 300

Delay to Output (Note 2)

Output Section

T_pd

V_{PIN 3}= 0 to 2V

Output Low Level

I_SINK= 20mA

I_SINK= 200mA

0.1 0.4

1.5 2.2

0.1 0.4

1.5 2.2

V

V_OL

Output High Level

I_SOURCE= 20mA

13 13.5

12 13.5

13 13.5

12 13.5

50 150

V

V_OH

I_SOURCE= 200mA

T_J= 25°C, C_L= 1nF

V_CC= 5V, I_SINK= 10mA

Rise Time (Note 2)

Fall Time (Note 2)

UVLO Saturation

T_R

T_F

V_SAT

50 150

0.7 1.2

ns

V

50 150

0.7 1.2

(Electrical Characteristics continue next page.)

Rev. 1.2a 10/25

3

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

ELECTRICAL CHARACTERISTICS (Con't.)

UC184xA/284xA

Min. Typ. Max. Min. Typ. Max.

UC384xA

Parameter

Symbol

Test Conditions

Units

Under-Voltage Lockout Section

Start Threshold

x842A/4A

x843A/5A

x842A/4A

x843A/5A

15

7.8 8.4 9.0 7.8 8.4 9.0

10 11 8.5 10 11.5

7.0 7.6 8.2 7.0 7.6 8.2

16

17 14.5 16 17.5

V

Min. Operation Voltage After Turn-On

9

PWM Section

Maximum Duty Cycle

x842A/3A

x844A/5A

94

47

96 100 94

96 100

%

48

50

0

47

48

50

0

Minimum Duty Cycle

Total Standby Section

Start-Up Current

0.3 0.5

mA

V

Operating Supply Current

Zener Voltage

I_CC

V_Z

11

35

17

11

35

17

I_CC= 25mA

30

Notes: 2. These parameters, although guaranteed, are not 100% tested in

production.

7. "Temperature stability, sometimes referred to as average temperature

coefficient, is described by the equation:

3. Parameter measured at trip point of latch with V_VFB= 0.

V_REF(max.) - V_REF(min.)

Temp Stability =

∆ V_COMP

T_J(max.) - T (min.)

J

4. Gain defined as: A_VOL

=

; 0 ≤ V_ISENSE≤ 0.8V.

∆ V_ISENSE

V_REF(max.) & V_REF(min.) are the maximum & minimum reference

voltage measured over the appropriate temperature range. Note that

the extremes in voltage do not necessarily occur at the extremes in

temperature."

5. Adjust V_CCabove the start threshold before setting at 15V.

6. Output frequency equals oscillator frequency for the UC1842A

and UC1843A. Output frequency is one half oscillator frequency

for the UC1844A and UC1845A.

BLOCK DIAGRAM

*

V_CC

34V

UVLO

V_REF

5.0V

50mA

5V

Ref

S / R

**

Hysteresis

6V (1842A/4A)

0.8V (1843A/5A)

GROUND

UVLO

16V (1842A/4A)

8.4V (1843A/5A)

Internal

Bias

2.5V

*

V_C

V_REF

Good Logic

R_T/C_T

Oscillator

***

T

OUTPUT

Error Amp

S

R

2R

R

V_FB

PWM

Latch

1V

**

POWER GROUND

Current Sense

Comparator

COMP

CURRENT SENSE

- V_CCand V_Care internally connected for 8 pin packages.

- POWER GROUND and GROUND are internally connected for 8 pin packages.

- Toggle flip flop used only in x844A and x845A series.

*

**

***

Rev. 1.2a 10/25

4

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

CHARACTERISTIC CURVES

FIGURE 1. — OSCILLATOR FREQUENCY vs. TIMING

RESISTOR

V_REF

8

C_T= 1nF

R_T

1M

R_T/C_T

4

5

C_T= 2.2nF

C_T

100k

GROUND

C_T= 4.7nF

10k

0

1.72

R_TC_T

For R_T> 5k, f »

Note: Output drive frequency is half the oscillator frequency for

the UCx844A/5A devices.

300

1.0k

3.0k

10.0k

30.0k

100k

R_T- (ohms)

FIGURE 2. — MAXIMUM DUTY CYCLE vs. TIMING RESISTOR

100.0

80.0

60.0

40.0

20.0

0

300

1.0k

3.0k

10.0k

30.0k

100k

R_T- (ohms)

Rev. 1.2a 10/25

5

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

TYPICAL APPLICATION CIRCUITS

FIGURE 4. — MOSFET PARASITIC OSCILLATIONS

FIGURE 3. — CURRENT SENSE SPIKE SUPPRESSION

V_CCDC BUS

V_CC

DC BUS

7

6

7

Q1

R_S

R₁

Q1

UCx84xA

6

5

I_PK

CHANGE

3

1.0V

R_S

I_PK(MAX)

=

C

5

R_S

The RC low pass filter will eliminate the leading edge current spike

caused by parasitics of Power MOSFET.

A resistor (R₁) in series with the MOSFET gate will reduce overshoot

& ringing caused by the MOSFET input capacitance and any

inductance in series with the gate drive. (Note: It is very important to

have a low inductance ground path to insure correct operation of the

I.C. This can be done by making the ground paths as short and as

wide as possible.)

FIGURE 5. — EXTERNAL DUTY CYCLE CLAMP AND MULTI-UNIT SYNCHRONIZATION

8

4

8

4

R_A

R_B

7

6

UCx84xA

555

TIMER

3

2

5

1

5

0.01

To other

UCx84xA devices

1.44

f =

(R_A+ 2R_B)C

R_B

Precision duty cycle limiting as well as synchronizing several parts is

possible with the above circuitry.

R_A+ 2R_B

Rev. 1.2a 10/25

6

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

TYPICAL APPLICATION CIRCUITS (continued)

FIGURE 6. — SLOPE COMPENSATION

V_CC

DC BUS

UCx84xA

7(12)

V_O

5V

8(14)

R_T

UVLO

S

5V

REF

R

INTERNAL

BIAS

2.5V

2N222A

V_REF

GOOD LOGIC

7(11)

6(10)

R_SLOPE

4(7)

OSCILLATOR

Q1

From V_O

C_T

C.S.

COMP

2R

R_i

2(3)

R_F

1V

ERROR

AMP

R

5(8)

3(5)

PWM

LATCH

R_d

C_F

R

1(1)

C

R_S

5(9)

Due to inherent instability of current mode converters running above 50% duty cycle, slope compensation should be added to either

the current sense pin or the error amplifier. Figure 6 shows a typical slope compensation technique.

FIGURE 7. — OPEN LOOP LABORATORY FIXTURE

V_REF

R_T

V_CC

A

UCx84xA

2N2222

100K

4.7K

1K

COMP

V_REF

1

2

3

4

8

7

6

5

V_FB

V_CC

0.1µF

ERROR AMP

ADJUST

1K

5K

I_SENSE

ADJUST

OUTPUT

4.7K

I_SENSE

OUTPUT

GROUND

R_TC_T

GROUND

C_T

High peak currents associated with capacitive loads necessitate careful grounding techniques. Timing and bypass capacitors should be

connected to pin 5 in a single point ground. The transistor and 5k potentiometer are used to sample the oscillator waveform and apply an

adjustable ramp to pin 3.

Rev. 1.2a 10/25

7

P R O D U C T D A T A B O O K 1 9 9 6 / 1 9 9 7

UC184xA/284xA/384xA

C U R R E N T M O D E P W M C O N T R O L L E R

P R O D U C T I O N D A T A S H E E T

TYPICAL APPLICATION CIRCUITS (continued)

FIGURE 8. — OFF-LINE FLYBACK REGULATOR

TI

MBR735

4.7kW 1W

220µF

250V

4.7kW

2W

3600pF

400V

1N4004

5V

2-5A

4700µF

10V

140kW

1/2W

1N4935

AC

INPUT

1N4004

1N4935

16V

10µF

20V

20kW

UC3844A

820pF

7

0.01µF

V_FB

V_CC

2

2.5kW

27kW

150kW

COMP

1

OUT

6

3

3.6kW

100pF

V_REF

8

4

1kW

470pF

CUR

SEN

10kW

0.85kW

R_T/C_T

GND

0.01µF

.0022µF

5

ISOLATION

BOUNDARY

SPECIFICATIONS

Input line voltage:

Input frequency:

Switching frequency:

Output power:

Output voltage:

Output current:

Line regulation:

Load regulation:

Efficiency @ 25 Watts,

V_IN= 90VAC:

90VAC to 130VAC

50 or 60Hz

40KHz 10%

25W maximum

5V +5%

2 to 5A

0.01%/V

8%/A*

* This circuit uses a low-cost feedback scheme in which the DC

voltage developed from the primary-side control winding is

sensed by the UC3844A error amplifier. Load regulation is

therefore dependent on the coupling between secondary and

control windings, and on transformer leakage inductance.

70%

V_IN= 130VAC:

65%

Output short-circuit current:

2.5Amp average

Rev. 1.2a 10/25

8


型号：	UC384XAM
厂家：	Microsemi
描述：	CURRENT MODEPWM CONTROLER 当前MODEPWM CONTROLER
文件：	总8页 (文件大小：381K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

UC384XAM [MICROSEMI]

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