MC33341P_技术文档

Order this document by MC33341/D

POWER SUPPLY

BATTERY CHARGER

REGULATION

The MC33341 is a monolithic regulation control circuit that is specifically

designed to close the voltage and current feedback loops in power supply

and battery charger applications. This device features the unique ability to

perform source high–side, load high–side, source low–side and load

low–side current sensing, each with either an internally fixed or externally

adjustable threshold. The various current sensing modes are accomplished

by a means of selectively using the internal differential amplifier, inverting

amplifier, or a direct input path. Positive voltage sensing is performed by an

internal voltage amplifier. The voltage amplifier threshold is internally fixed

and can be externally adjusted in all low–side current sensing applications.

An active high drive output is provided to directly interface with economical

optoisolators for isolated output power systems. This device is available in

8–lead dual–in–line and surface mount packages.

CONTROL CIRCUIT

SEMICONDUCTOR

TECHNICAL DATA

8

1

• Differential Amplifier for High–Side Source and Load Current Sensing

• Inverting Amplifier for Source Return Low–Side Current Sensing

• Non–Inverting Input Path for Load Low–Side Current Sensing

• Fixed or Adjustable Current Threshold in All Current Sensing Modes

• Positive Voltage Sensing in All Current Sensing Modes

P SUFFIX

PLASTIC PACKAGE

CASE 626

• Fixed Voltage Threshold in All Current Sensing Modes

8

• Adjustable Voltage Threshold in All Low–Side Current Sensing Modes

• Output Driver Directly Interfaces with Economical Optoisolators

• Operating Voltage Range of 2.3 V to 16 V

1

D SUFFIX

PLASTIC PACKAGE

CASE 751

Representative Block Diagram

(SO–8)

Current Sense Input B/

Voltage Threshold Adjust

Drive

Output

Voltage Sense

Input

V

CC

7

8

6

5

PIN CONNECTIONS

Current Sense

Differential

Amp

Drive Output

1

2

3

4

8

7

6

5

Input A

Voltage and Current

Transconductance

Amp/Driver

1.0

Current Threshold

Adjust

V

CC

V

Current Sense Input B/

Voltage Threshold Adjust

Compensation

Gnd

1.2 V

0.2 V

1.0

I

Voltage Sense Input

Inverting/

Noninverting Amp

Reference

(Top View)

ORDERING INFORMATION

Operating

1

2

3

4

Temperature Range

Device

Package

Current Sense

Input A

Current

Threshold Adjust

Compensation

Gnd

MC33341D

MC33341P

SO–8

T

= –25° to +85°C

A

This device contains 114 active transistors.

Plastic DIP

This document contains information on a new product. Specifications and information herein

Motorola, Inc. 1996

Rev 0

are subject to change without notice.

1

MOTOROLA ANALOG IC DEVICE DATA

MC33341

MAXIMUM RATINGS

Rating

Symbol

Value

Unit

V

Power Supply Voltage (Pin 7)

V

CC

16

Voltage Range

V

IR

–1.0 to V

V

CC

Current Sense Input A (Pin 1)

Current Threshold Adjust (Pin 2)

Compensation (Pin 3)

Voltage Sense Input (Pin 5)

Current Sense Input B/Voltage Threshold Adjust (Pin 6)

Drive Output (Pin 8)

Drive Output Source Current (Pin 8)

I

50

mA

Source

Thermal Resistance, Junction–to–Air

P Suffix, DIP Plastic Package, Case 626

D Suffix, SO–8 Plastic Package, Case 751

R

°C/W

θJA

100

178

Operating Junction Temperature (Note 1)

Storage Temperature

T

–25 to +150

–55 to +150

°C

J

T

stg

NOTE: ESD data available upon request.

ELECTRICAL CHARACTERISTICS (V

CC

= 6.0 V, T = 25°C, for min/max values T is the operating junction

A A

temperature range that applies (Note 1), unless otherwise noted.)

Characteristic

Symbol

Min

Typ

Max

Unit

CURRENT SENSING (Pins 1, 2, 6)

High–Side Source and Load Sensing Pin 1 to Pin 6 (Pin 1 >1.6 V)

V

mV

th(I HS)

th(I LS+)

th(I LS–)

Internally Fixed Threshold Voltage (Pin 2 = V

)

CC

T

A

= 25°C

187

183

–

197

–

10

207

211

–

T

A

= T

to T

low high

Externally Adjusted Threshold Voltage (Pin 2 = 0 V)

Externally Adjusted Threshold Voltage (Pin 2 = 200 mV)

–

180

–

Low–Side Load Sensing Pin 1 to Pin 4 (Pin 1 = 0 V to 0.8 V)

V

mV

Internally Fixed Threshold Voltage (Pin 2 = V

)

CC

T

A

= 25°C

194

192

–

200

–

10

206

208

–

T

A

= T

to T

low high

Externally Adjusted Threshold Voltage (Pin 2 = 0 V)

Externally Adjusted Threshold Voltage (Pin 2 = 200 mV)

–

180

–

Low–Side Source Return Sensing Pin 1 to 4 (Pin 1 = 0 V to –0.2 V)

Internally Fixed Threshold Voltage (Pin 2 = V

)

CC

T

= 25°C

–195

–193

–

–201

–

–10

–180

–207

–209

–

A

T

= T

to T

A

low high

Externally Adjusted Threshold Voltage (Pin 2 = 0 V)

Externally Adjusted Threshold Voltage (Pin 2 = 200 mV)

–

Current Sense Input A (Pin 1)

Input Bias Current, High–Side Source and Load Sensing

I

–

40

10

–

µA

nA

kΩ

IB(A HS)

(Pin 2 = 0 V to V

V)

Pin 6

Input Bias Current, Low–Side Load Sensing

(Pin 2 = 0 V to 0.8 V)

I

IB(A LS+)

Input Resistance, Low–Side Source Return Sensing

(Pin 2 = –0.6 V to 0 V)

R

in(A LS–)

Current Sense Input B/Voltage Threshold Adjust (Pin 6)

Input Bias Current

I

IB(B)

High–Side Source and Load Current Sensing (Pin 6 > 2.0 V)

Voltage Threshold Adjust (Pin 6 < 1.2 V)

–

20

100

–

µA

nA

Current Sense Threshold Adjust (Pin 2)

Input Bias Current

I

–

10

–

nA

IB(I th)

Transconductance, Current Sensing Inputs to Drive Output

g

m(I)

–

6.0

–

mhos

NOTE: 1. Tested ambient temperature range for the MC33341: T

= –25°C, T

= +85°C.

high

low

2

MOTOROLA ANALOG IC DEVICE DATA

MC33341

ELECTRICAL CHARACTERISTICS (continued) (V

temperature range that applies (Note 1), unless otherwise noted.)

= 6.0 V, T = 25°C, for min/max values T is the operating junction

CC

A

Characteristic

Symbol

Min

Typ

Max

Unit

DIFFERENTIAL AMPLIFIER DISABLE LOGIC (Pins 1, 6)

Logic Threshold Voltage Pin 1 (Pin 6 = 0 V)

V

Enabled, High–Side Source and Load Current Sensing

Disabled, Low–Side Load and Source Return Current Sensing

V

–

≥1.7

≤1.3

–

th(I HS)

th(I LS)

VOLTAGE SENSING (Pins 5, 6)

Positive Sensing Pin 5 to Pin 4

V

th(V)

Internally Fixed Threshold Voltage

T

= 25°C

1.186

1.174

–

1.210

–

40

1.234

1.246

–

V

mV

V

A

T

= T

to T

A

low high

Externally Adjusted Threshold Voltage (Pin 6 = 0 V)

Externally Adjusted Threshold Voltage (Pin 6 = 1.2 V)

–

1.175

–

Voltage Sense, Input Bias Current (Pin 5)

Transconductance, Voltage Sensing Inputs to Drive Output

DRIVE OUTPUT (Pin 8)

I

–

10

–

nA

IB(V)

g

7.0

mhos

m(V)

High State Source Voltage (I

= 10 mA)

V

–

V

– 0.8

CC

20

–

V

Source

OH

High State Source Current (Pin 8 = 0 V)

TOTAL DEVICE (Pin 7)

I

15

mA

Source

Operating Voltage Range

V

2.5 to 15

–

2.3 to 15

300

–

V

CC

Power Supply Current (V

= 6.0 V)

I

600

µA

CC

NOTE: 1. Tested ambient temperature range for the MC33341: T

low

= –25°C, T

= +85°C.

high

PIN FUNCTION DESCRIPTION

Name

Description

1

Current Sense Input A

This multi–mode current sensing input can be used for either source high–side, load high–side,

source–return low–side, or load low–side sensing. It is common to a Differential Amplifier, Inverting

Amplifier, and a Noninverting input path. Each of these sensing paths indirectly connect to the current

sense input of the Transconductance Amplifier. This input is connected to the high potential side of a

current sense resistor when used in source high–side, load high–side, or load low–side current

sensing modes. In source return low–side current sensing mode, this pin connects to the low potential

side of a current sense resistor.

2

3

Current Threshold Adjust

Compensation

The current sense threshold can be externally adjusted over a range of 0 V to 200 mV with respect to

Pin 4, or internally fixed at 200 mV by connecting Pin 2 to V

.

CC

This pin is connected to a high impedance node within the transconductance amplifier and is made

available for loop compensation. It can also be used as an input to directly control the Drive Output.

An active low at this pin will force the Drive Output into a high state.

4

5

Ground

This pin is the regulation control IC ground. The control threshold voltages are with respect to this pin.

Voltage Sense Input

This is the voltage sensing input of the Transconductance Amplifier. It is normally connected to the

power supply/battery charger output through a resistor divider. The input threshold is controlled by

Pin 6.

6

Current Sense Input B/

Voltage Threshold Adjust

This is a dual function input that is used for either high–side current sensing, or as a voltage threshold

adjustment for Pin 5. This input is connected to the low potential side of a current sense resistor when

used in source high–side or load high–side current sensing modes. In all low–side current sensing

modes, Pin 6 is available as a voltage threshold adjustment for Pin 5. The threshold can be externally

adjusted over a range of 0 V to 1.2 V with respect to Pin 4, or internally fixed at 1.2 V by connecting

Pin 6 to V

.

CC

7

8

V

This is the positive supply voltage for the regulation control IC. The typical operating voltage range is

2.3 V to 15 V with respect to Pin 4.

CC

Drive Output

This is a source–only output that normally connects to a linear or switching regulator control circuit.

This output is capable of 15 mA, allowing it to directly drive an optoisolator in primary side control

applications where galvanic isolation is required.

3

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 2. Current Sensing

Figure 1. Voltage Sensing

Threshold Change versus Temperature

4.0

1.0

V

= 6.0 V

V

= 6.0 V

CC

0

–4.0

–1.0

3

2

1

–8.0

–12

–2.0

–3.0

1 – Source High–Side and Load High–Side

2 – Source Return Low–Side

3 – Load Low–Side

–50

–25

0

25

50

75

C)

100

125

–50

–25

0

25

50

75

C)

100

125

T , AMBIENT TEMPERATURE (

°

T , AMBIENT TEMPERATURE (

°

A

Figure 3. Closed–Loop Voltage Sensing Input

versus Voltage Threshold Adjust

Figure 4. Closed–Loop Current Sense Input B

versus Current Threshold Adjust

1.6

1.4

1.2

1.0

0.8

0.6

0

16

0

V

I

= 6.0 V

= 1.0 V

= 1.0 mA

= 25°C

CC

O

A

V

CC

14

12

10

8.0

–40

–80

2.0

4.0

6.0

8.0

10

V

–V

Pin 1 Pin 6

T

V

I

= 6.0 V

= 1.0 V

= 1.0 mA

CC

O

V

Pin 6

–120

Pin 1 = V

T

V

CC

Pin 5

= 25

°C

A

–160

–200

–240

–280

6.0

4.0

2.0

0

Differential Amplifier is active for

source high–side and load high–side

current sensing. Both vertical axis are

0.4

0.2

0

12

V

–V

Pin 6 Pin 5

expressed in millivolts down to V

.

CC

14

0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

0

40

80

120

160

200

240

280

V , VOLTAGE THRESHOLD ADJUST (V)

Pin 6

V , CURRENT THRESHOLD ADJUST (V)

Pin 2

Figure 5. Closed–Loop Current Sensing Input A

versus Current Threshold Adjust

Figure 6. Closed–Loop Current Sensing Input A

versus Current Threshold Adjust

280

240

200

160

120

80

0

–40

14

12

10

14

12

10

Noninverting input path is active

for load low–side current sensing.

V

I

= 6.0 V

= 1.0 V

= 1.0 mA

= 25°C

CC

O

A

Gnd

V

= 6.0 V

= 1.0 V

= 1.0 mA

Pin 5

CC

O

–80

T

I

O

T

= 25

°C

–120

–160

–200

8.0

6.0

4.0

8.0

6.0

4.0

A

V

Pin 5

V

–|V |

Pin 2 Pin 1

V

–V

Pin 2 Pin 1

Inverting Amplifier is

40

0

–240

–260

2.0

0

active for source return

low–side current sensing.

2.0

0

Gnd

240

0

40

80

120

160

200

280

0

40

80

120

160

200

240

280

V

, CURRENT THRESHOLD ADJUST (mV)

V , CURRENT THRESHOLD ADJUST (mV)

Pin 2

4

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 8. Bode Plot

Figure 7. Bode Plot

Current Sensing Inputs to Drive Output

Voltage Sensing Inputs to Drive Output

60

50

40

60

50

40

30

20

10

0

80

Phase

Low–Side Sensing

Phase

High–Side Sensing

Phase

100

120

100

120

Gain

30

20

10

0

Gain

140

160

180

140

160

180

V

R

= 6.0 V

= 1.0 V

= 1.0 k

V

= 6.0 V

CC

= 1.0 V

R = 1.0 k

L

O

L

O

Pin 3 = 1.0 nF

= 25

Pin 3 = 1.8 nF

= 25

T

°C

T

°C

A

1.0 k

10 k

100 k

1.0 M

10 k

100 k

1.0 M

f, FREQUENCY (Hz)

Figure 9. Transconductance

Voltage Sensing Inputs to Drive Output

Figure 10. Transconductance

Current Sensing Inputs to Drive Output

8.0

6.0

8.0

6.0

V

T

= 6.0 V

= 1.0 V

V

= 6.0 V

CC

O

CC

V = 1.0 V

O

= 25

°C

T = 25°C

A

4.0

2.0

0

2.0

0

0.1

0.2 0.3

0.5

1.0

2.0 3.0

5.0

10

0.1

0.2 0.3

0.5

1.0

2.0 3.0

5.0

10

I

, DRIVE OUTPUT LOAD CURRENT (mA)

I

, DRIVE OUTPUT LOAD CURRENT (mA)

O

Figure 11. Drive Output High State

Source Saturation versus Load Current

Figure 12. Supply Current

versus Supply Voltage

0

–0.4

–0.8

–1.2

–1.6

–2.0

1.0

0.8

0.6

0.4

0.2

0

V

T

= 6.0 V

CC

= 25°C

Drive Output High State

V

CC

A

I

T

= 0 mA

O

= 25°C

A

Drive Output Low State

0

4.0

8.0

12

16

20

0

4.0

8.0

, SUPPLY VOLTAGE (V)

CC

12

16

I , OUTPUT LOAD CURRENT (mA)

V

L

5

MOTOROLA ANALOG IC DEVICE DATA

MC33341

noninverting I

input of the transconductance amplifier. In

INTRODUCTION

sen

order to allow for maximum circuit flexibility, there are three

methods of current sensing, each with different internal

paths.

In source high–side (Figures 13 and 14)andloadhigh–side

(Figures 17 and 18) current sensing, the Differential Amplifier

is active with a gain of 1.0. Pin 1 connects to the high potential

Power supplies and battery chargers require precise

control of output voltage and current in order to prevent

catastrophic damage to the system load. Many present day

power sources contain a wide assortment of building blocks

and glue devices to perform the required sensing for proper

regulation. Typical feedback loop circuits may consist of a

voltage and current amplifier, level shifting circuitry, summing

circuitry and a reference. The MC33341 contains all of these

basic functions in a manner that is easily adaptable to many

of the various power source–load configurations.

side of current sense resistor R while Pin 6 connects to the

S

low side. Logic circuitry is provided to disable the Differential

Amplifier output whenever low–side current sensing is

required. This circuit clamps the Differential Amplifier output

high which disconnects it from the I

TransconductanceAmplifier. This happens if Pin 1 is lessthan

1.2 V or if Pin 1 is less than Pin 6.

input of the

sen

OPERATING DESCRIPTION

The MC33341 is an analog regulation control circuit that is

specifically designed to simultaneously close the voltage and

current feedback loops in power supply and battery charger

applications. This device can control the feedback loop in

either constant–voltage or constant–current mode with

automatic crossover. A concise description of the integrated

circuit blocks is given below. Refer to the block diagram in

Figure 13.

With source return low–side current sensing (Figures 15

and 16), the Inverting Amplifier is active with a gain of –1.0.

Pin 1 connects to the low potential side of current sense

resistor R while Pin 4 connects to the high side. Note that a

S

negative voltage appears across R with respect to Pin 4.

S

In load low–side current sensing (Figures 19 and 20) a

Noninverting input path is active with a gain of 1.0. Pin 1

connects to the high potential side of current sense resistor

Transconductance Amplifier

R

while Pin 4 connects to the low side. The Noninverting

S

A quad input transconductance amplifier is used to control

the feedback loop. This amplifier has separate voltage and

current channels, each with a sense and a threshold input.

Within a given channel, if the sense input level exceeds that

of the threshold input, the amplifier output is driven high. The

channel with the largest difference between the sense and

threshold inputs will set the output source current of the

amplifier and thus dominate control of the feedback loop. The

amplifier output appears at Pin 8 and is a source–only type

that is capable of 15 mA.

A high impedance node within the transconductance

amplifier is made available at Pin 3 for loop compensation.

This pin can sink and source up to 10 µA of current. System

stability is achieved by connecting a capacitor from Pin 3 to

ground. The Compensation Pin signal is out of phase with

respect to the Drive Output. By actively clamping Pin 3 low,

the Drive Output is forced into a high state. This, in effect, will

shutdown the power supply or battery charger, by forcing the

output voltage and current regulation threshold down

towards zero.

input path lies from Pin 1, through the Inverting Amplifier

input and feedback resistors R, to the cathode of the output

diode. With load low–side current sensing, Pin 1 will be more

positive than Pin 4, forcing the Inverting Amplifier output low.

This causes the diode to be reverse biased, thus preventing

the output stage of the amplifier from loading the input signal

that is flowing through the feedback resistors.

The regulation threshold in all of the current sensing

modes is internally fixed at 200 mV with Pin 2 connected to

V

. Pin 2 can be used to externally adjust the threshold over

CC

a range of 0 to 200 mV with respect to the IC ground at Pin 4.

Reference

An internal band gap reference is used to set the 1.2 V

voltage threshold and 200 mV current threshold. The

reference is initially trimmed to a ±1.0% tolerance at

T

= 25°C and is guaranteed to be within ±2.0% over an

A

ambient operating temperature range of –25° to 85°C.

Applications

Each of the application circuits illustrate the flexibility of

this device. The circuits shown in Figures 13 through 20

contain an optoisolator connected from the Drive Output at

Pin 8 to ground. This configuration is shown for ease of

understanding and would normally be used to provide an

isolated control signal to a primary side switching regulator

controller. In non–isolated, primary or secondary side

applications, a load resistor can be placed from Pin 8 to

ground. This resistor will convert the Drive Output current to

a voltage for direct control of a regulator.

Voltage Sensing

The voltage that appears across the load is monitored by

the noninverting V

This voltage is resistively scaled down and connected to

Pin 5. The threshold at which voltage regulation occurs is set

by the level present at the inverting V

transconductance amplifier. This level is controlled by Pin 6.

In source high–side and load high–side current sensing

modes, Pin 6 must be connected to the low potential side of

input of the transconductance amplifier.

sen

input of the

th

current sense resistor R . Under these conditions, the

In applications where excessively high peak currents are

possible from the source or load, the load induced voltage

S

voltage regulation threshold is internally fixed at 1.2 V. In

source return low–side and load low–side current sensing

modes, Pin 6 is available, and can be used to lower the

regulation threshold of Pin 5. This threshold can be externally

adjusted over a range of 0 V to 1.2 V with respect to the IC

ground at Pin 4.

drop across R could exceed 1.6 V. Depending upon the

S

current sensing configuration used, this will result in forward

biasing of either the internal V

clamp diode, Pin 6, or the

CC

device substrate, Pin 1. Under these conditions, input series

resistor R3 is required. The peak input current should be

limited to 20 mA. Excessively large values for R3 will

degrade the current sensing accuracy. Figure 21 shows a

Current Sensing

Current sensing is accomplished by monitoring the

method of bounding the voltage drop across R without

S

voltage that appears across sense resistor R level shifting

S,

sacrificing current sensing accuracy.

it with respect to Pin 4 if required, and applying it to the

6

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 13. Source High–Side Current Sensing with

Internally Fixed Voltage and Current Thresholds

R

S

Source

Load

R2

R3

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Comp

Source

Return

Load

The above figure shows the MC33341 configured for source high–side current sensing allowing a common ground path

between Load – and Source Return –. The Differential Amplifier inputs, Pins 1 and 6, are used to sense the load induced

voltage drop that appears across resistor R . The internal voltage and current regulation thresholds are selected by the

S

respective external connections of Pins 2 and 6. Resistor R3 is required in applications where a high peak level of reverse

current is possible if the source inputs are shorted. The resistor value should be chosen to limit the input current of the internal

V

clamp diode to less than 20 mA. Excessively large values for R3 will degrade the current sensing accuracy.

CC

V

R2

R1

th(I HS)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

0.2

R2

R1

1.2

1

R

S

7

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 14. Source High–Side Current Sensing with

Externally Adjustable Current and Internally Fixed Voltage Thresholds

R

S

Source

Load

R2

R3

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Current

Control

Comp

Source

Return

Load

The above figure shows the MC33341 configured for source high–side current sensing with an externally adjustable current

threshold. Operation of this circuit is similar to that of Figure 13. The current regulation threshold can be adjusted over a range

of 0 V to 200 mV with respect to Pin 4.

V

R2

R1

th(Pin 2)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

R2

R1

1.2

1

8

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 15. Source Return Low–Side Current Sensing with

Internally Fixed Current and Voltage Thresholds

Source

Load

R2

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Comp

R3

R

Source

Return

S

Load

The above figure shows the MC33341 configured for source return low–side current sensing allowing a common power path

between Source + and Load +. This configuration is especially suited for negative output applications where a common ground

path, Source + to Load +, is desired. The Inverting Amplifier inputs, Pins 1 and 4, are used to sense the load induced voltage

drop that appears across resistor R . The internal voltage and current regulation thresholds are selected by the respective

S

external connections of Pins 2 and 6. Resistor R3 is required in applications where high peak levels of inrush current are

possible. The resistor value should be chosen to limit the negative substrate current to less than 20 mA. Excessively large

values for R3 will degrade the current sensing accuracy.

V

R2

R1

th(I LS–)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

–0.2

R2

R1

1.2

1

R

S

9

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 16. Source Return Low–Side Current Sensing with

Externally Adjustable Current and Voltage Thresholds

Source

Load

R2

Voltage

Control

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Current

Control

Comp

R3

R

Source

Return

S

Load

The above figure shows the MC33341 configured for source return low–side current sensing with externally adjustable voltage

and current thresholds. Operation of this circuit is similar to that of Figure 15. The respective voltage and current regulation

threshold can be adjusted over a range of 0 to 1.6 V and 0 V to 200 mV with respect to Pin 4.

V

R2

R1

th(Pin 2)

V

1

I

R

– 0.6

reg

th(Pin 6)

I

–

pk

S

reg

R

R3

S

0.02

10

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 17. Load High–Side Current Sensing with

Internally Fixed Current and Voltage Thresholds

Source

Load

R

R2

S

R3

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Comp

Source

Return

Load

The above figure shows the MC33341 configured for load high–side current sensing allowing common paths for both power

and ground, between the source and load. The Differential Amplifier inputs, Pins 1 and 6, are used to sense the load induced

voltage drop that appears across resistor R . The internal voltage and current regulation thresholds are selected by the

S

respective external connections of Pins 2 and 6. Resistor R3 is required in applications where high peak levels of load current

are possible from the battery or load bypass capacitor. The resistor value should be chosen to limit the input current of the

internal V

clamp diode to less than 20 mA. Excessively large values for R3 ill degrade the current sensing accuracy.

CC

V

R2

R1

th(I HS)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

0.2

R2

R1

1.2

1

R

S

11

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 18. Load High–Side Current Sensing with

Externally Adjustable Current and Internally Fixed Voltage Thresholds

Source

Load

R2

R

S

R3

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

Current

Control

Comp

Source

Return

Load

The above figure shows the MC33341 configured for load high–side current sensing with an externally adjustable current

threshold. Operation of this circuit is similar to that of Figure 17. The current regulation threshold can be adjusted over a range

of 0 V to 200 mV with respect to Pin 4.

V

R2

R1

th(Pin 2)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

R2

R1

1.2

1

12

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 19. Load Low–Side Current Sensing with

Internally Fixed Current and Voltage Thresholds

Source

Load

R2

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

R3

R

Comp

S

Source

Return

Load

The above figure shows the MC33341 configured for load low–side current sensing allowing common paths for both power and

ground, between the source and load. The Noninverting input paths, Pins 1 and 4, are used to sense the load induced voltage

drop that appears across resistor R . The internal voltage and current regulation thresholds are selected by the respective

S

external connections of Pins 2 and 6. Resistor R3 is required in applications where high peak levels of load current are possible

from the battery or load bypass capacitor. The resistor value should be chosen to limit the negative substratecurrent to less than

20 mA. Excessively large values for R3 will degrade the current sensing accuracy.

V

R2

R1

th(I LS

)

V

1

I

R

– 0.6

reg

th(V)

I

pk

S

reg

R

R3

S

0.02

0.2

R2

R1

1.2

1

R

S

13

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 20. Load Low–Side Current Sensing with

Externally Adjustable Current and Voltage Thresholds

Source

Load

R2

Voltage

Current

8

7

6

5

V

CC

V

CC

V

CC

R1

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

Opto

Isolator

V

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Battery or

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

R3

Current

Control

R

S

Comp

Source

Return

Load

The above figure shows the MC33341 configured for load low–side current sensing with an externally adjustable voltage and

current threshold. Operation of this circuit is similar to that of Figure 19. The respective voltage and current regulation threshold

can be adjusted over a range of 0 to 1.2 V and 0 V to 200 mV, with respect to Pin 4.

V

R2

R1

th(Pin 2)

V

1

I

R

– 0.6

reg

th(Pin 6)

I

pk

S

reg

R

R3

S

0.02

14

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 21. Current Sense Resistor Bounding

Source

Load

R

S

8

1

7

6

5

4

Input

Short

Output

Short

MC33341

2

3

Source

Return

Load

NOTE: An excessive load induced voltage across R can occur if either the source input or load output is shorted. This voltage can

S

easily be bounded with the addition of the diodes shown without degrading the current sensing accuracy. This bounding technique

can be used in any of the MC33341 applications where high peak currents are anticipated.

Figure 22. Multiple Output Current and Voltage Regulation

Source

Load

Output 2

8

1

7

6

5

4

MC33341

2

3

Source

Output 1

Opto

Isolator

8

1

7

6

5

4

MC33341

2

3

Source

Return

Output Common

NOTE: Multiple outputs can be controlled by summing the error signal into a common optoisolator. The converter output with the largest

voltage or current error will dominate control of the feedback loop.

15

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 23. 10 V/1.0 A Constant–Voltage Constant–Current Regulator

0.2

MTP2955

Input

Output

12 V to 16 V

10 V/1.0 A

82.5 k

8

7

6

5

V

CC

V

CC

V

CC

11.1 k

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

V

10

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

Variable

Resistive

Load

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

0.01

3.0 k

Input

Ground

Output

Ground

Figure 24. Output Load Regulation

10

8.0

6.0

4.0

2.0

0

0.2

0 4

0.6

0.8

1.0

I

, OUTPUT LOAD CURRENT (A)

O

Figure 23 shows the MC33341 configured as a source high–side constant–voltage constant–current regulator. The regulator is

designed for an output voltage of 10 V at 1.0 A. Figure 24 shows the regulator’s output characteristics as the load is varied.

Source return low–side, load high–side, and load low–side configurations will each exhibit a nearly identical load regulation

characteristic. A heatsink is required for the MTP2955 series pass element.

16

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Figure 25. Constant–Current Constant–Voltage Switch Mode Charger

200 µH

MTP2955

0.25

Input

12 V

Output

5.87 V/800 mA

1N5821

100

68 k

3.0 k

8

7

6

5

V

CC

V

CC

V

CC

1.2 V

Differential Amp

Disable Logic

1.2 V

V

0.4 V

sen

Transconductance

Amp

V

100

CC

V

th

V

Differential Amp

R

I

sen

R

I

th

V

CC

R

Reference

CC

V

R

CC

0.2 V 0.4 V 1.2 V

V

CC

0.2 V

Inverting Amp

1

2

3

4

12 k

Input

Ground

Output

Ground

Figure 25 shows that the MC33341 can be configured as a high–side constant–current constant–voltage switch mode charger.

This circuit operates as a step down converter. With a nominal input voltage and output load current as stated above, the

switching frequency is approximately 28 kHz with and an associated conversion efficiency of 86 percent. The switching fre-

quency will vary with changes in input voltage and load current.

17

MOTOROLA ANALOG IC DEVICE DATA

MC33341

OUTLINE DIMENSIONS

P SUFFIX

PLASTIC PACKAGE

CASE 626–05

ISSUE K

8

5

NOTES:

1. DIMENSION L TO CENTER OF LEAD WHEN

–B–

FORMED PARALLEL.

2. PACKAGE CONTOUR OPTIONAL (ROUND OR

SQUARE CORNERS).

1

4

3. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

F

MILLIMETERS

INCHES

–A–

NOTE 2

DIM

A

B

C

D

F

G

H

J

K

L

M

N

MIN

9.40

6.10

3.94

0.38

1.02

MAX

10.16

6.60

4.45

0.51

1.78

MIN

MAX

0.400

0.260

0.175

0.020

0.070

L

0.370

0.240

0.155

0.015

0.040

C

2.54 BSC

0.100 BSC

0.76

0.20

2.92

1.27

0.30

3.43

0.030

0.008

0.115

0.050

0.012

0.135

J

–T–

SEATING

PLANE

N

7.62 BSC

0.300 BSC

M

–––

10

–––

10

D

K

0.76

1.01

0.030

0.040

G

H

M

0.13 (0.005)

T

A

B

D SUFFIX

PLASTIC PACKAGE

CASE 751–05

(SO–8)

NOTES:

D

A

ISSUE R

1. DIMENSIONING AND TOLERANCING PER ASME

Y14.5M, 1994.

2. DIMENSIONS ARE IN MILLIMETERS.

3. DIMENSION D AND E DO NOT INCLUDE MOLD

PROTRUSION.

4. MAXIMUM MOLD PROTRUSION 0.15 PER SIDE.

5. DIMENSION B DOES NOT INCLUDE MOLD

PROTRUSION. ALLOWABLE DAMBAR

PROTRUSION SHALL BE 0.127 TOTAL IN EXCESS

OF THE B DIMENSION AT MAXIMUM MATERIAL

CONDITION.

8

1

5

4

C

M

0.25

B

H

E

MILLIMETERS

B

e

DIM

A

A1

B

C

D

MIN

1.35

0.10

0.35

0.18

4.80

3.80

MAX

1.75

0.25

0.49

0.25

5.00

4.00

h X 45

A

C

SEATING

PLANE

E

e

H

h

L

1.27 BSC

0.10

5.80

0.25

0.40

0

6.20

0.50

1.25

7

A1

B

L

M

S

0.25

C

B

A

18

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding

the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and

specificallydisclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters which may be provided in Motorola

datasheetsand/orspecificationscananddovaryindifferentapplicationsandactualperformancemayvaryovertime. Alloperatingparameters,including“Typicals”

must be validated for each customer application by customer’s technical experts. Motorola does not convey any license under its patent rights nor the rights of

others. Motorola products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other

applicationsintended to support or sustain life, or for any other application in which the failure of the Motorola product could create a situation where personal injury

ordeathmayoccur. ShouldBuyerpurchaseoruseMotorolaproductsforanysuchunintendedorunauthorizedapplication,BuyershallindemnifyandholdMotorola

and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees

arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that

Motorola was negligent regarding the design or manufacture of the part. Motorola and

Opportunity/Affirmative Action Employer.

are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal

19

MOTOROLA ANALOG IC DEVICE DATA

MC33341

Mfax is a trademark of Motorola, Inc.

How to reach us:

USA/EUROPE/Locations Not Listed: Motorola Literature Distribution;

P.O. Box 5405, Denver, Colorado 80217. 303–675–2140 or 1–800–441–2447

JAPAN: Nippon Motorola Ltd.; Tatsumi–SPD–JLDC, 6F Seibu–Butsuryu–Center,

3–14–2 Tatsumi Koto–Ku, Tokyo 135, Japan. 81–3–3521–8315

Mfax : RMFAX0@email.sps.mot.com – TOUCHTONE 602–244–6609

INTERNET: http://Design–NET.com

ASIA/PACIFIC: Motorola Semiconductors H.K. Ltd.; 8B Tai Ping Industrial Park,

51 Ting Kok Road, Tai Po, N.T., Hong Kong. 852–26629298

20

MOTOROLA ANALOG IC DEVICE DATA

MC33341/D

◊


型号：	MC33341P
厂家：	MOTOROLA
描述：	POWER SUPPLY BATTERY CHARGER REGULATION CONTROL CIRCUIT 电源电池充电器调节控制电路电源电路电池电源管理电路光电二极管
文件：	总20页 (文件大小：377K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

MC33341P [MOTOROLA]

相关型号：

MC33341PG

MC33341_06

MC33342

MC33342D

MC33342DG

MC33342DR1

MC33342DR2

MC33342DR2G

MC33342P

MC33342PG

MC33345DTB

MC33345DW