ISL6421 Datasheet, PDF(7/10 Page) Intersil Corporation – Single Output LNB Supply and Control Voltage Regulator with I2C Interface for Advanced Satellite Set-top Box Designs

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

ISL6421 Datasheet, PDF (7/10 Pages) Intersil Corporation – Single Output LNB Supply and Control Voltage Regulator with I2C Interface for Advanced Satellite Set-top Box Designs

◁

ISL6421

Output Timing

The programmed output voltage rise and fall times can be

set by an external capacitor. The output rise and fall times

will be approximately 3400 times the TCAP value. For the

recommended range of 0.47ÂµF to 2.2ÂµF, the rise and fall

time would be 1.6ms to 7.6ms. Using a 0.47ÂµF capacitor

insures the PWM stays below its overcurrent threshold when

charging a 120ÂµF VSW filter cap during the worst case 13V

to 19V transition. A typical value of 1.0ÂµF is recommended.

This feature affects the programmed voltage rise and fall

times.

Current Limiting (Only one ISEL option needed)

The current limiting block can operate either statically

(simple current clamp) or dynamically. The threshold is

between 575mA and 950mA. When the DCL (Dynamic

Current Limiting) bit is set to LOW, the over current

protection circuit works dynamically. That is, as soon as an

overload is detected, the output is shutdown for a time tOFF,

typically 900ms. Simultaneously the overload flag (OLF) bit

of the system register is set to HIGH. After this time has

elapsed, the output is resumed for a time Ton = 20ms.

During Ton, the device output will be current limited to

between 575mA and 950mA. At the end of Ton, if the

overload is still detected, the protection circuit will cycle

again through Toff and Ton. At the end of a full Ton during

which no overload is detected, normal operation is resumed

and the OLF bit is reset to LOW. Typical Ton+Toff time is

920ms as determined by an internal timer. This dynamic

operation can greatly reduce the power dissipation in a short

circuit condition, still ensuring excellent power-on start-up in

most conditions.

However, there could be some cases in which a highly

capacitive load on the output may cause a difficult start-up,

when the dynamic protection is chosen. This can be solved

by initiating a power start-up in static mode (DCL = HIGH)

and then switching to the dynamic mode (DCL = LOW) after

a chosen amount of time. When in static mode, the OLF bit

goes HIGH when the current clamp limit is reached and

returns LOW when the overload condition is cleared. The

OLF bit will be LOW at the end of initial power-on soft-start.

Thermal Resistance

This IC is protected against overheating. When the junction

temperature exceeds 150Â°C (typical), the step-up converter

and the linear regulator are shut off and the overtemp flag

(OTF) bit of the SR is set HIGH. Normal operation is

resumed and the OTF bit is reset LOW, when the junction is

cooled down to 130Â°C (typical).

External Output Voltage Selection

The output voltage can be selected by the I2C bus.

Additionally, the QFN package offers a pin (SEL18V) for

independent 13V/18V output voltage selection. When using

this pin, the I2C bits should be initialized to 13V status.

I2C BITS

TABLE 1.

SEL18V

O/P VOLTAGE

13V

Low

13V

High

18V

I2C Bus Interface for ISL6421

(Refer to Philips I2C Specification, Rev. 2.1)

Data transmission from main microprocessor to the ISL6421

and vice versa takes place through the 2 wires I2C bus

interfaces, consisting of the two lines SDA and SCL. Both

SDA and SCL are bidirectional lines, connected to a positive

supply voltage via a pull up resistor. (Pull up resistors to

positive supply voltage must be externally connected). When

the bus is free, both lines are HIGH. The output stage of

ISL6421 will have an open drain/open collector in order to

perform the wired-AND function. Data on the I2C bus can be

transferred up to 100kbits/s in the standard-mode or up to

400kbits/s in the fast-mode. The level of logic â0â and logic

â1â is dependent of associated value of Vdd as per electrical

specification table. One clock pulse is generated for each

data bit transferred.

Data Validity

The data on the SDA line must be stable during the HIGH

period of the clock. The HIGH or LOW state of the data line

can only change when the clock signal on the SCL line is

LOW. Refer to Figure 1.

SDA

SCL

DATA LINE CHANGE

STABLE OF DATA

DATA VALID ALLOWED

FIGURE 1. DATA VALIDITY

START and STOP Conditions

As shown in the Figure 2, START condition is a HIGH to

LOW transition of the SDA line, while SCL is HIGH. The

STOP condition is a LOW to HIGH transition on the SDA

line, while SCL is HIGH. A STOP condition must be sent

before each START condition.

SDA

SCL

START

CONDITION

STOP

CONDITION

FIGURE 2. START AND STOP WAVEFORMS

▷