LTM8026_1208 LINER [Linear Technology], LTM8026_1208 Datasheet - Page 17

LTM8026_1208

Manufacturer Part Number

LTM8026_1208

Description

36VIN, 5A CVCC Step-Down ?Module Regulator

Manufacturer

LINER [Linear Technology]

Datasheet

1.LTM8026_1208.pdf (26 pages)

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applicaTions inForMaTion

LTM8026s equally sharing output current is shown in the

Typical Applications section. The modulation of the CTL_I

inputs is performed at a high bandwidth, so use an op

amp with a gain bandwidth product greater than 1MHz.

The example circuit in the Typical Applications section

uses the LTC6255, which has a minimum gain bandwidth

product of 2MHz.

The LTM8026’s CVCC operation provides the ability to

power share the load among several input voltage sources.

An example of this is shown in the Typical Applications

section; please refer to the schematic while reading this

discussion. Suppose the application powers 2.5V at 8A

and the system under consideration has regulated 24V

and 12V input rails available. The power budget for the

power rails says that each can allocate only 750mA to

produce 2.5V. From the Input Current vs Output Current

graph in the Typical Performance Characteristics section

for 2.5V

than 5A output current, so apply a 66.5k/140k from V

to the CTL_I pin of the LTM8026 powered from 24V

set the output current to 5A. These resistor values were

derived as follows:

1. The typical output current limit is 5.6A for CTL_I = 1.5V

2. To get 5A, make the voltage on CTL_I = 1.5V • 5A/5.6A

3. The V

The LTM8026 powered from 12V

rest of the load current, or 3A. Again referring to the Input

Current vs Output Current graph in the Typical Performance

Characteristics section for 2.5V

more than 3A when operated from 12V

similar to the above, apply a resistor network of 132k/78.7k

to the CTL_I pin:

1. To get 2.5A, make the voltage on CTL_I = 1.5V • 3A/5.6A

2. Applying a 132k/88.7k network to V

and above.

= 1.34V.

66.5k/140k network yields 2V • 140k/(66.5k + 140k) =

1.35V

= 0.8V

2V • 88.7k/(88.7k + 132k) = 0.8V

OUT

REF

, 750mA from the 24V rail can support more

node is a regulated 2V, so applying the

OUT

, 750mA will support

needs to supply the

REF

. Using a method

and CTL_I yields

REF

Figure 5. Layout Showing Suggested External Components, GND

Plane and Thermal Vias.

As seen in the graph accompanying the schematic in the

Typical Applications section, the input currents to each

LTM8026 stays below 750mA for all loads below 8A.

PCB Layout

Most of the headaches associated with PCB layout have

been alleviated or even eliminated by the high level of

integration of the LTM8026. The LTM8026 is neverthe-

less a switching power supply, and care must be taken to

minimize EMI and ensure proper operation. Even with the

high level of integration, you may fail to achieve specified

operation with a haphazard or poor layout. See Figure 5

for a suggested layout. Ensure that the grounding and

heat sinking are acceptable.

A few rules to keep in mind are:

1. Place the R

2. Place the C

GND

their respective pins.

and GND connection of the LTM8026.

•

THERMAL AND INTERCONNECT VIAS

OUT

ADJ

capacitor as close as possible to the V

OUT

and R

•

OUT

•

resistors as close as possible to

•

GND

•

GND

•

LTM8026

•

8026 F05

SYNC

RUN

8026fa

LTM8026_1208 LINER [Linear Technology], LTM8026_1208 Datasheet - Page 17

LTM8026_1208

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