Maxim MAX767TCAP, MAX767RCAP, MAX767REAP, MAX767SCAP, MAX767SEAP Datasheet

...
19-0224; Rev 2; 8/94
Evaluation Kit Manual
Follows Data Sheet
5V-to-3.3V, Synchronous, Step-Down
_______________General Description
The MAX767 is a high-efficiency, synchronous buck controller IC dedicated to converting a fixed 5V supply into a tightly regulated 3.3V output. Two key features set this device apart from similar, low-voltage step-down switching regulators: high operating frequency and all N-channel construction in the application circuit. The 300kHz operating frequency results in very small, low­cost external surface-mount components.
The inductor, at 3.3µH for 5A, is physically at least five times smaller than inductors found in competing solu­tions. All N-channel construction and synchronous rectifi­cation result in reduced cost and highest efficiency. Efficiency exceeds 90% over a wide range of loading, eliminating the need for heatsinking. Output capacitance requirements are low, reducing board space and cost.
The MAX767 is a monolithic BiCMOS IC available in 20-pin SSOP packages. For other fixed output voltages and package options, please consult the factory.
________________________Applications
Local 5V-to-3.3V DC-DC Conversion Microprocessor Daughterboards Power Supplies up to 10A or More
________Typical Application Circuit
Power-Supply Controller
____________________________Features
>90% Efficiency700µA Quiescent Supply Current120µA Standby Supply Current4.5V-to-5.5V Input RangeLow-Cost Application CircuitAll N-Channel SwitchesSmall External ComponentsTiny Shrink-Small-Outline Package (SSOP)Predesigned Applications:
Standard 5V to 3.3V DC-DC Converters up to 10A High-Accuracy Pentium P54C VR-Spec Supply
Fixed Output Voltages Available:
3.3V (Standard)
3.45V (High-Speed Pentium™)
3.6V (PowerPC™)
______________Ordering Information
PART TEMP. RANGE
MAX767CAP 0°C to +70°C 20 SSOP MAX767RCAP 0°C to +70°C 20 SSOP MAX767SCAP 0°C to +70°C 20 SSOP MAX767TCAP 0°C to +70°C 20 SSOP ±1.2% 3.3V MAX767C/D 0°C to +70°C Dice*
Ordering Information continued at end of data sheet.
*
Contact factory for dice specifications.
PIN-
PACKAGE
REF. TOL.
±1.8% ±1.8% ±1.8%
V
OUT
3.3V
3.45V
3.6V
MAX767
INPUT
4.5V TO 5.5V
V
ON
CC
MAX767
REF
™ Pentium is a trademark of Intel. PowerPC is a trademark of IBM.
BST
DH
LX
DL
PGND
CS
FB
GND
________________________________________________________________
3.3µH
OUTPUT
3.3V
AT 5A
__________________Pin Configuration
TOP VIEW
CS
1
SS
2
ON
3
GND GND GND
GND
REF
SYNC
V
CC
MAX767
4 5 6 7 8 9
10
SSOP
Maxim Integrated Products
Call toll free 1-800-998-8800 for free samples or literature.
FB
20
DH
19
LX
18
BST
17
DL
16
V
15
CC
V
14
CC
PGND
13
N.C.
12
GND
11
1
5V-to-3.3V, Synchronous, Step-Down Power-Supply Controller
ABSOLUTE MAXIMUM RATINGS
VCCto GND.................................................................-0.3V, +7V
PGND to GND........................................................................±2V
BST to GND...............................................................-0.3V, +15V
LX to BST.....................................................................-7V, +0.3V
Inputs/Outputs to GND
(ON, REF, SYNC, CS, FB, SS) .....................-0.3V, V
DL to PGND .....................................................-0.3V, V
MAX767
DH to LX...........................................................-0.3V, BST + 0.3V
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
CC CC
+ 0.3V + 0.3V
ELECTRICAL CHARACTERISTICS
(VCC= ON = 5V, GND = PGND = SYNC = 0V, I
PARAMETER
VCCInput Supply Range
0mV < (CS - FB) < 80mV,
Output Voltage (FB)
Load Regulation 2.5 %(CS - FB) = 0mV to 80mV Line Regulation VCCFault Lockout Voltage Current-Limit Voltage SS Source Current SS Fault Sink Current
Reference Voltage (REF) VCCStandby Current
VCCQuiescent Current Oscillator Frequency Oscillator SYNC Range
SYNC High Pulse Width SYNC Low Pulse Width 200 ns SYNC Rise/Fall Time
Oscillator Maximum Duty Cycle Input Low Voltage Input High Voltage Input Current ±1 µA
DL Sink/Source Current 1 A DH Sink/Source Current DL On Resistance DH On Resistance
4.5V < V (includes load and line regulation)
VCC= 4.5V to 5.5V Falling edge, hysteresis = 1% CS - FB
MAX767, MAX767R, MAX767S MAX767T ON = 0V, VCC= 5.5V FB = CS = 3.5V SYNC = 3.3V SYNC = 0V or 5V
Not tested SYNC = 3.3V SYNC = 0V SYNC, ON ON SYNC SYNC, ON = 0V or 5V DL = 2V (BST - LX) = 4.5V, DH = 2V High or low High or low, (BST - LX) = 4.5V
CC
REF
< 5.5V
= 0mA, TA= T
CONDITIONS
REF Short to GND.......................................................Momentary
REF Current.........................................................................20mA
Continuous Power Dissipation (TA= +70°C)
20-Pin SSOP (derate 8.00mW/°C above +70°C) ..........640mW
Operating Temperature Ranges:
MAX767CAP/MAX767_CAP.................................0°C to +70°C
MAX767EAP/MAX767_EAP ..............................-40°C to +85°C
Lead Temperature (soldering, 10sec).............................+300°C
to T
MIN
MAX767, MAX767T MAX767R MAX767S
, unless otherwise noted. Typical values are at TA= +25°C.)
MAX
MIN TYP MAX
4.5 5.5 V
3.17 3.35 3.46
3.32 3.50 3.60
3.46 3.65 3.75
0.1 %
3.80 4.20 80 100 120 mV
2.50 4 6.5
2 mA
3.24 3.30 3.36
3.26 3.30 3.34
120 200
0.7 1.0 mA
260 300 340
200 240 350 kHz 200
89 92
95
2.40
V
- 0.5
CC
1
UNITS
200 ns
0.8 V
7 7
V
V
µA
V
µA
kHz
ns
%
V
A
Ω Ω
2 _______________________________________________________________________________________
5V-to-3.3V, Synchronous, Step-Down
Power-Supply Controller
__________________________________________Typical Operating Characteristics
(Circuit of Figure 1 (5A configuration), VIN= 5V, oscillator frequency = 300kHz, TA= +25°C, unless otherwise noted.)
EFFICIENCY vs. OUTPUT CURRENT
(1.5A CIRCUIT)
100
90
80
70
EFFICIENCY (%)
60
50
0.001 0.1 10
0.01 1 OUTPUT CURRENT (A)
EFFICIENCY vs. OUTPUT CURRENT
(7A CIRCUIT)
100
90
MAX767-01
EFFICIENCY (%)
MAX767-04
EFFICIENCY vs. OUTPUT CURRENT
(3A CIRCUIT)
100
90
80
70
60
50
0.001 0.1 10
0.01 1 OUTPUT CURRENT (A)
EFFICIENCY vs. OUTPUT CURRENT
(10A CIRCUIT)
100
90
100
MAX767-02
EFFICIENCY (%)
1000
MAX767-05
100
EFFICIENCY vs. OUTPUT CURRENT
(5A CIRCUIT)
90
80
70
60
50
0.001 0.1 10
0.01 1 OUTPUT CURRENT (A)
SWITCHING FREQUENCY vs.
PERCENT OF FULL LOAD
SYNC = REF (300kHz)
MAX767
MAX767-03
MAX767-06
80
70
EFFICIENCY (%)
60
50
0.001 0.1 10
0.01 1 OUTPUT CURRENT (A)
IDLE-MODE WAVEFORMS
= 300mA
I
LOAD
5µs/div
80
70
EFFICIENCY (%)
60
50
0.001 0.1 10
0.01 1 OUTPUT CURRENT (A)
3.3V OUTPUT 50mV/div, AC COUPLED
LX 5V/div
I
LOAD
10
1
0.1
SWITCHING FREQUENCY (kHz)
0.01
0.001 1 100
PWM-MODE WAVEFORMS
= 5A
1µs/div
0.01 0.1 10
LOAD CURRENT (% FULL LOAD)
3.3V OUTPUT 50mV/div, AC COUPLED
LX 5V/div
_______________________________________________________________________________________
3
5V-to-3.3V, Synchronous, Step-Down Power-Supply Controller
____________________________Typical Operating Characteristics (continued)
(Circuit of Figure 1 (5A configuration), VIN= 5V, oscillator frequency = 300kHz, TA= +25°C, unless otherwise noted.)
1.5A CIRCUIT LOAD-TRANSIENT RESPONSE
MAX767
5A CIRCUIT LOAD-TRANSIENT RESPONSE
200µs/div
1.5A LOAD CURRENT
0A
3.3V OUTPUT
50mV/div AC-COUPLED
5A
LOAD CURRENT
0A
3.3V OUTPUT
50mV/div AC-COUPLED
3A CIRCUIT LOAD-TRANSIENT RESPONSE
3A
LOAD CURRENT
0A
3.3V OUTPUT 50mV/div AC-COUPLED
200µs/div
7A CIRCUIT LOAD-TRANSIENT RESPONSE
7A
LOAD CURRENT
0A
3.3V OUTPUT 50mV/div AC-COUPLED
200µs/div
200µs/div
10A CIRCUIT LOAD-TRANSIENT RESPONSE
10A
LOAD CURRENT
0A
3.3V OUTPUT 50mV/div AC-COUPLED
200µs/div
4 _______________________________________________________________________________________
5V-to-3.3V, Synchronous, Step-Down
Power-Supply Controller
______________________________________________________________Pin Description
PIN
1
2 SS Soft-start input. Ramp time to full current limit is 1ms/nF of capacitance to GND. 3 ON
4–7, 11 GND Low-current analog ground. Feedback reference point for the output.
8 REF 3.3V internal reference output. Bypass to GND with 0.22µF minimum capacitor.
9 SYNC
10, 14, 15 V
12 N.C. No internal connection 13 PGND Power ground 16 17 BST Boost capacitor connection (0.1µF) 18 LX Inductor connection. Can swing 2V below GND without latchup. 19 DH Gate-drive output for the high-side MOSFET 20 FB Feedback and current-sense input for the PWM
NAME FUNCTION
CS Current-sense input: +100mV = nominal current-limit level referred to FB.
ON/O—F—F–control input to disable the PWM. Tie directly to VCCfor automatic start-up.
Oscillator control/synchronization input. Connect to VCCor GND for 200kHz; connect to REF for 300kHz. For external clock synchronization in the 240kHz to 350kHz range, a high-to-low transition causes a new cycle to start.
CC
Supply voltage input: 4.5V to 5.5V
DL Gate-drive output for the low-side synchronous rectifier MOSFET
MAX767
SHUTDOWN
ON/OFF
C5
(OPTIONAL)
C6
0.22µF
Figure 1. Standard Application Circuit
0.01µF
4.7µF
C4
ON
SS
SYNC
REF
V
CC
MAX767
GND
R2
10
BST
PGND
INPUT
4.5V TO 5.5V
D1 SMALL- SIGNAL  SCHOTTKY
DH
LX
DL
CS
FB
C3
N1
0.1µF
D2
N2
C1
OUTPUT
L1
R1
3.3V
C2
_______________________________________________________________________________________ 5
5V-to-3.3V, Synchronous, Step-Down Power-Supply Controller
_____Standard Application Circuits
This data sheet shows five predesigned circuits with output current capabilities from 1.5A to 10A. Many users will find one of these standard circuits appropri­ate for their needs. If a standard circuit is used, the remainder of this data sheet (
Applications Information and Design Procedure
MAX767
be bypassed. Figure 1 shows the Standard Application Circuit. Table 1
gives component values and part numbers for five dif­ferent implementations of this circuit: 1.5A, 3A, 5A, 7A, and 10A output currents.
Each of these circuits is designed to deliver the full rated output load current over the temperature range listed. In addition, each will withstand a short circuit of several seconds duration from the output to ground. If the circuit must withstand a continuous short circuit, refer to the required changes.
Good layout is necessary to achieve the designed out­put power, high efficiency, and low noise. Good layout includes the use of a ground plane, appropriate com­ponent placement, and correct routing of traces using appropriate trace widths. The following points are in order of decreasing importance.
1. A ground plane is essential for optimum perfor­mance. In most applications, the circuit will be located on a multilayer board and full use of the four or more copper layers is recommended. Use the top and bottom layers for interconnections and the inner layers for an uninterrupted ground plane.
2. Because the sense resistance values are similar to a few centimeters of narrow traces on a printed cir­cuit board, trace resistance can contribute signifi­cant errors. To prevent this, Kelvin connect CS and FB to the sense resistor; i.e., use separate traces not carrying any of the inductor or load current, as shown in Figure 2. These signals must be carefully shielded from DH, DL, BST, and the LX node.
Important: place the sense resistor as close as pos­sible to and no further than 10mm from the MAX767.
3. Place the LX node components N1, N2, L1, and D2 as close together as possible. This reduces resis­tive and switching losses and confines noise due to ground inductance.
4. The input filter capacitor C1 should be less than 10mm away from N1’s drain. The connecting cop­per trace carries large currents and must be at least 2mm wide, preferably 5mm.
Short-Circuit Duration
Detailed Description
section for the
Layout and Grounding
and
) can
5. Keep the gate connections to the MOSFETs short for low inductance (less than 20mm long and more than 0.5mm wide) to ensure clean switching.
6. To achieve good shielding, it is best to keep all switching signals (MOSFET gate drives DH and DL, BST, and the LX node) on one side of the board and all sensitive nodes (CS, FB, and REF) on the other side.
7. Connect the GND and PGND pins directly to the ground plane, which should ideally be an inner layer of a multilayer board.
_______________Detailed Description
Note:
The remainder of this document contains the detailed information necessary to design a circuit that differs substantially from the five standard application circuits. If you are using one of the predesigned stan­dard circuits, the following sections are provided only for your reading pleasure.
The MAX767 converts a 4.5V to 5.5V input to a 3.3V output. Its load capability depends on external compo­nents and can exceed 10A. The 3.3V output is generat­ed by a current-mode, pulse-width-modulation (PWM) step-down regulator. The PWM regulator operates at either 200kHz or 300kHz, with a corresponding trade­off between somewhat higher efficiency (200kHz) and smaller external component size (300kHz). The MAX767 also has a 3.3V, 5mA reference voltage. Fault­protection circuitry shuts off the output should the refer­ence lose regulation or the input voltage go below 4V (nominally).
External components for the MAX767 include two N­channel MOSFETs, a rectifier, and an LC output filter. The gate-drive signal for the high-side MOSFET, which must exceed the input voltage, is provided by a boost circuit that uses a 0.1µF capacitor. The synchronous rectifier keeps efficiency high by clamping the voltage across the rectifier diode. An external low-value cur­rent-sense resistor sets the maximum current limit, pre­venting excessive inductor current during start-up or under short-circuit conditions. An optional external capacitor sets the programmable soft-start, reducing in-rush surge currents upon start-up and providing adjustable power-up time.
The PWM regulator is a direct-summing type, lacking a traditional integrator-type error amplifier and the phase shift associated with it. It therefore does not require external feedback-compensation components, as long as you follow the ESR guidelines in the
Information and Design Procedure
sections.
Applications
6 _______________________________________________________________________________________
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