HIP0080 データシートの表示（PDF） - Intersil

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HIP0080

Quad Inverting Power Drivers with Serial Diagnostic Interface

Intersil 

HIP0080, HIP0081

Diagnostic Interface Overview

Each Quad Inverting Power Driver IC may be used as a single

power switching driver, with or without the diagnostic interface.

Where more than 4 Power Driver Switches are required, the

HIP0080 or HIP0081 may be used in a multiple IC cascade

connection. In cascade operation, the diagnostic data from all

chips is read as a single serial sequence of fault bits. As shown

in the Functional Block Diagram each output stage has voltage

and temperature sensors to detect fault conditions while

comparators and delay filters process the data. Four bits of

diagnostic information is provided as fault feedback from each

of the four output stages. When detected, the diagnostic data is

put in a parallel diagnostic data register. Using the diagnostic

control interface to address the system (one or more ICs in

cascade), the fault data is transferred from the parallel

diagnostic data register to a serial diagnostic data register as a

sequence of 16 bits for each IC.

All diagnostic data bits may be read using the Chip Select (CS)

and the Clock (CLK) inputs. The CLK input must be low, when

CS goes active low. After reading the first bit at DO to

determine if there is an error flag, the following 16 bits of serial

diagnostic data may be clocked out of DO. Clocking the CLK

input synchronously shifts the serial register data out of DO

while cascaded data (from other devices or sources) is shifted

into the DI input. As data is shifted out of DO, the parallel

diagnostic data register is cleared on the first rising edge of the

CLK input, following the CS low. After each 16 clocks,

cascaded diagnostic data from the next IC in sequence is then

shifted out of the DO output. Shifting the serial diagnostic data

out of DO is done as a continuous sequence, reading the data

from all ICs in cascade while CS remains low. New diagnostic

data can be stored in the parallel diagnostic data registers on

each IC while the existing serial diagnostic data is read.

Referring to Figure 1 and Figure 2, there are two sources that

generate an OR’ed Fault Flag at DO when CS goes low. The

two fault data sources are (1) the on-chip fault detection and (2)

the off-chip DI input from front end ICs in the cascade. The fault

data bit, labeled DF (Data Fault) in Figure 2, contains the OR’ed

inputs from both sources. The DF bit is not part of the 16-bit

serial diagnostic data sequence. In cascaded operation, the DI

input for the first of the selected chips should be tied low. And,

in single IC operation (no cascade), the DI input should also be

tied low. In cascaded operation, the Error Flags are cascaded

via the DI inputs.

The on-chip fault Error Flag goes high if any one of the 16

diagnostic data fault bits have been set HIGH. This fault Error

Flag bit precedes the 16 diagnostic data fault bits and is OR’ed

with all diagnostic data fault bits. The DF bit flags the presence

of an Error Flag fault on the IC and in any part of the cascaded

string, including DI data input. As shown in Figure 3 each IC in

the cascade provides an output which is passed to the DI input

of the following IC and is passed on as an OR’ed bit to the DO

output of the last IC in the cascade. A fault condition is

immediately evident without reading all diagnostic data bits.

However, all bits must be read to determine which chip and

which diagnostic bit has been set. The Fault Flag is reset by the

CLK input when the bits are read. When no fault condition is

detected, it is not necessary to toggle the CLK input. When a

fault is detected, at least one toggle of the clock is needed to

reset the parallel diagnostic register which clears the register of

all detected fault states.

The last IC in the string ORs its own 16 fault bits in the parallel

diagnostic register data and sends this data bit to an Error Flag

register. The Error Flag register outputs the presence of a fault

in one or more bits of the parallel diagnostic data register. As

shown in Figure 2, the Error Flag is the first bit in front of the

serial register and is input to OR Gate, U7 with the DI input. The

DI input passes through AND Gate, U6 when the GATE signal

is high and output via the amplifier U8 to DO. The output

amplifier U8 is active only while CS is low. When CS is low, the

RS Flip-Flop drives the GATE output high. When the GATE is

high, the cascaded DF bits are jammed from DI to DO. All Error

Flags in the cascade are cleared (by the CLK input) when the

serial diagnostic data is clocked out of DO.

The GATE is an internal control signal that is forced high when

the CLK input is low and CS goes low. The GATE will remain

high, even when CS is returned to a high state, provided the

CLK input has not changed from a low state. This condition still

applies when fault data is detected. The DO output is not

latched; however, the Error Flag is latched when CS goes low

and will not be updated until the next time CS goes low. The

fault data is preserved as long as the CLK input does not go

high. If the CLK is high when CS goes low, the GATE will be

disabled and no cascade data will be shifted from DI to DO.

Under normal conditions, the CLK signal goes high to switch

the GATE low and simultaneously shifts the first of 16

diagnostic data bits out of the serial diagnostic data register to

DO. The CS low input is not latched and must be held low while

all data is shifted out of DO.

The diagnostic interfaces to the HIP0080 and HIP0081 are SPI

compatible. The microcontroller is programmed to control the

read and respond action based on the diagnostic readout.

Normally the CS input is addressed and DO is read. If a fault is

indicated by the Error Flag, all data is shifted out of DO and

processed to determine the diagnostic fault condition. The Error

Flag bit does require a separate input back to the

microcontroller to initiate the serial data shift. When the CLK

signal starts, the serial sequence starting with the first of the 16

serial diagnostic bits is input to the microcontroller.

Serial Register Data Sequence

The fault data follows the Serial Register Data Sequence of

Table 1 in bit sequence and, in cascade, by IC sequence. In

each of the 4 power switching output channels, the

diagnostic sense circuits set 1-bit in the parallel diagnostic

register for each of the 4 diagnostics fault conditions. A total

of 16 diagnostics data bits are shifted to the serial register

when CS goes low. Table 1 shows the order and sequence

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