ADP1046DC1-EVALZ Analog Devices, ADP1046DC1-EVALZ Datasheet - Page 27

ADP1046DC1-EVALZ

Manufacturer Part Number

ADP1046DC1-EVALZ

Description

Daughter Cards & OEM Boards ADP1046 Daughter Card

Manufacturer

Analog Devices

Series

ADP1046r

Datasheet

1.ADP1046DC1-EVALZ.pdf (92 pages)

Specifications of ADP1046DC1-EVALZ

Rohs

yes

Product

Daughter Cards

Description/function

100 kHz daughter board

Interface Type

I2C

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 40 C

Operating Supply Voltage

3.3 V

Factory Pack Quantity

For Use With

ADP1046

Current page: 27 of 92
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Data Sheet

POWER SUPPLY SYSTEM AND FAULT MONITORING

The

capabilities. The system monitoring functions include voltage,

current, power, and temperature readings. The fault conditions

include out-of-limit values for current, voltage, power, and

temperature. The limits for the fault conditions are programmable.

The

certain programmed thresholds or limits are exceeded. These

thresholds and limits are described in the Fault Registers section.

FLAGS

The

certain limits, conditions, and thresholds are exceeded. The

real-time status of these flags can be read in Register 0x00

to Register 0x03. The response to these flags is individually

programmable. Flags can be ignored or used to trigger actions

such as turning off certain PWM outputs or the OrFET gate.

Flags can also be used to turn off the power supply. The

can be programmed to respond when these flags are reset. For

more information, see the Fault Registers section.

The

(Register 0x04 to Register 0x07). The latched fault registers

have the same flags as Register 0x00 to Register 0x03, but the

flags in the latched registers remain set so that intermittent

faults can be detected. Reading a latched fault register resets

all the flags in that register.

MONITORING FUNCTIONS

The

voltages, currents, power, and temperature. All these values are

stored in separate registers and can be read through the I

interface. For more information, see the Value Registers section.

VOLTAGE READINGS

The VS1, VS2, and VS3 ADCs have an input range of 1.6 V.

The outputs of the ADCs are 12-bit values, which means that

the LSB size is 1.6 V/4096 = 390.625 μV. The user is limited to

an input range of 1.4 V, which means that the ADC output code

is limited to 1.4 V/390.6 μV = 3584.

The equation to calculate the ADC code at a specified voltage

(Vx) at the pin is given by the following formula:

For example, when there is 1 V on the input of the ADC,

In a 12 V application, the 12 V reading is divided down using

a resistor divider network to provide 1 V at the sense pin.

Therefore, to convert the register value to a real voltage, use

the following formula:

ADP1046

ADC Code = Vx/1.6 × 4096

ADC Code = 1 V/1.6 × 4096

ADC Code = 2560

OUT

= (LSB × 2560) × ((R1 + R2)/R2)

has extensive system and fault monitoring

has an extensive set of flags that are set when

also has a set of latched fault registers

monitors and reports several signals, including

ADP1046

Rev. B | Page 27 of 92

In a 12 V system, this equates to

CURRENT READINGS

CS1 Pin

CS1 has an input range of 1.4 V. The ADC performs a 12-bit

reading conversion of this value, which means that the LSB size

is 1.4 V/4096 = 341.8 μV.

When there is exactly 1 V on the CS1 pin, the value in the CS1

value register (Register 0x13[15:4]) reads 2926.

The equation to calculate the ADC code at a specified CS1

input voltage (Vx) is given by the following formula:

For example, when there is 1 V on the CS1 input pin,

CS2+, CS2− Pins

The full-scale (FS) range for the CS2 ADC can be set to 60 mV

or 120 mV using Register 0x27[5].

The CS2 ADC has an input range of 120 mV. The resolution is

12 bits, which means that the LSB size is 120 mV/4096 = 29.30 μV.

The user is limited to an input range of 110 mV.

The equation to calculate the ADC code at a specified voltage

For example, when there is 50 mV on the input of the ADC,

Therefore, to convert the CS2 register value to a real current,

use the following formula:

where:

CS2_ADC_CODE is the value in Register 0x18[15:4].

FS is the full-scale voltage drop (60 mV or 120 mV).

For example, if CS2_ADC_CODE = 1520, R

FS = 120 mV, the real current is calculated as follows:

SENSE

) is given by the following formula:

ADC Code = Vx/1.4 × 4096

ADC Code = 1 V/1.4 × 4096

ADC Code = 2926

ADC Code = Vx/(120 mV) × 4096

ADC Code = 50 mV/120 mV × 4096

ADC Code = 1707

OUT

is the sense resistor value.

OUT

= (CS2_ADC_CODE/4096) × (FS/R

= (1520/4096) × (120 mV/10 mΩ)

= 4.453 A

= (390.625 μV × 2560) × (11 kΩ + 1 kΩ)/1 kΩ

SENSE

= 10 mΩ, and

)

ADP1046

ADP1046DC1-EVALZ Analog Devices, ADP1046DC1-EVALZ Datasheet - Page 27

ADP1046DC1-EVALZ

Specifications of ADP1046DC1-EVALZ

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