ADP8863 Analog Devices, ADP8863 Datasheet - Page 14

ADP8863

Manufacturer Part Number

ADP8863

Description

Charge Pump, 7-Channel Fun Lighting LED Driver

Manufacturer

Analog Devices

Datasheet

1.ADP8863.pdf (52 pages)

Specifications of ADP8863

Vin Range

2.5 to 5.5V

Vout (v)

4.3 to 5.5

Synchronous

Package

20-Lead LFCSP,20-Lead WLCSP

Led Configuration

Parallel

Topology

Capacitive

I2c Support

Yes

Max Iout (ma)

60mA

Brightness Control

I2C

Peak Efficiency (%)

89%

Switching Frequency

1.32MHz

Over Volt Protection (v)

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ADP8863ACPZ-R7

Manufacturer:

ADI/亚德诺

Quantity:

20 000

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ADP8863

LED GROUPINGS

Each LED can respond individually or be grouped together

into the backlight controls. By default, all LEDs are set to be

part of the backlight. This is changed by setting Bits[6:0] in

be enabled individually in Register 0x10. They can also all be

enabled simultaneously via the SIS_EN bit in Register 0x01.

Any LEDs configured for the backlight can only be enabled

via the BL_EN bit in Register 0x01.

LED CURRENT SETTINGS

Any of the LED outputs (Pin D1 to Pin D7) can be used to

drive any color of LED at 0 mA to 30 mA, provided that the

LED’s Vf is less than 4.1 V. Additionally, the D7 sink can regu-

late up to 60 mA. The current settings are determined by a

7-bit code programmed by the user into Register 0x14 through

allows the user to set the LED to one of 128 different levels.

The ADP8863 can implement two distinct algorithms to

achieve a linear or a nonlinear relationship between input

code and diode output current. The law and SC_LAW bits

in Register 0x04 and Register 0x0F, respectively, are used to

change between these algorithms.

By default, the ADP8863 uses a linear algorithm (law and

SC_LAW = 00), where the LED current increases linearly for

a corresponding increase in input code. LED current (in

milliamperes) is determined by the following equation:

where:

Code is the input code programmed by the user.

Full-Scale Current is the maximum sink current allowed per

LED (typically 30 mA).

The ADP8863 can also implement a nonlinear (square

approximation) relationship between input code and LED

current. In this case (law and SC_LAW = 01, 10, or 11), the LED

current (in milliamperes) is determined by the following

equation:

Figure 29 shows the LED current level vs. input code for both

the linear and square law algorithms.

LED Current (mA) = Code × (Full-Scale Current/127)

LED

Current

(

)

⎛

⎜

⎝

Code

Full

−

Scale

127

Current

⎞

⎟

⎠

Rev. A | Page 14 of 52

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AUTOMATED FADE IN AND FADE OUT

The LED drivers are easily configured for automated fade in

and fade out. Sixteen fade in and fade out rates can be selected

via the I

0.0 sec to 5.5 sec (per full-scale current, either 30 mA or 60 mA).

The backlight LEDs have separate fade in and fade out time

controls from the independent sink LEDs.

Table 5. Available Fade In and Fade Out Rates

Code

0000

0001

0010

0011

0100

0101

0110

0111

1000

1001

1010

1011

1100

1101

1110

1111

The fade profile is based on the transfer law selected (linear,

square, Cubic 10, or Cubic 11) and the delta between the actual

current and the target current. Smaller changes in current

reduce the fade time. For linear and square law fades, the fade

time is given by

where the Fade Rate is shown in Table 5.

Fade Time = Fade Rate × (Code/127)

C interface. Fade in and fade out rates range from

Figure 29. LED Current vs. Input Code

Fade Rate (in sec per Full-Scale Current)

0.0 (disabled)

0.3

0.6

0.9

1.2

1.5

1.8

2.1

2.4

2.7

3.0

3.5

4.0

4.5

5.0

5.5

LINEAR

CODE

SQUARE

128

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ADP8863 Analog Devices, ADP8863 Datasheet - Page 14

ADP8863

Specifications of ADP8863

Available stocks

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