HOLTIC HI-8470

HI-8470
16-Channel Discrete-to-Digital Sensor
with ARINC 429 Transmitter
May 2013
DESCRIPTION
FEATURES
The HI-8470 is a sixteen channel discrete-to-digital
interface device. The IC has 16 channels which can sense
Open/Ground or 28V/Open signal levels. The voltage
threshold of the sensors is user programmable with
external resistors. Sense input thresholds may also be set
to CMOS logic levels to interface the part with other
sensors, for example an external ADC or resolver.
!
Pin programmable - requires no MCU or software
control (no need for DO-178 certification)
!
Robust CMOS Silicon-on-Insulator (SOI) technology
!
16 threshold-selectable discrete input channels
!
Programmable Thresholds and Hysteresis
!
Sense Detection Range 3V to 22V
!
On-chip ARINC 429 Transmitter and Line Driver
!
3.3 V single supply operation
!
Pin programmable transmit repetition rate
!
Internal lightning protection circuitry for both discrete
sense lines and line driver allows compliance with
RTCA/DO-160G, Section 22 Level 3 Pin Injection
Tests.
!
Adjustable sense thresholds
!
DO-254 certifiable
An on-chip ARINC 429 transmitter / line driver allows the
status of discrete lines to be transmitted in ARINC 429
format with pin-programmed label byte value, repetition
rate and transmission speed. Complete operation of the
HI-8470 is controlled by CMOS logic pins, negating the
need for a MCU or software in the application.
A single 1 MHz clock source is required for ARINC 429 bit
timing and word transmission rate scheduling.
The on-chip ARINC 429 Line Driver operates from a single
3.3V power supply, using an integrated DC/DC converter
to generate the required bipolar line voltages.
The discrete sense pins and line driver outputs are
lightning protected to RTCA/DO-160G, Section 22 Level 3
Pin Injection Test Waveform Set A (3 & 4), Set B (3 & 5A)
and Set Z (3 & 5B) without the use of any external
components.
TYPICAL APPLICATION
Digital Logic GND/Open
Lines
Discretes
28V/Open
Discretes
3.3V
CLOCK
LINE DRIVER
+
ARINC 429 WORD ASSEMBLER
ARINC 429
BUS
ARINC 429
TRANSMITTER
-
ARINC 429
SCHEDULER
DC/DC
CONVERTER
HI-8470
ARINC 429
Label
Hard-wired ARINC 429
Transmission
Configuration
Figure 1
(DS8470 Rev. A)
HOLT INTEGRATED CIRCUITS
www.holtic.com
05/13
HI-8470
BLOCK DIAGRAM
VWET
SO15:0
BIT31:27
VLOGIC
EXTTHSOG
HI
P
VOLTAGE
REFERENCE
LO
31
THSHIOG
THSLOOG
30
EXTTHSVO
CLKIN
29
HI
VOLTAGE
REFERENCE
28
LO
POR
27
THSHIVO
THSLOVO
MR
26
ARINC 429
MESSAGE
SCHEDULER
24
TMR7:0
TEST1
TEST0
23
TXENB
25
VWET
22
VLOGIC
SPEED
23.8K
SEL15
SI15
-
3.3K
29K
LIGHTNING
PROTECTION
20
+
19
18
+
-
17
360K
16
40K
15
14
SI14
SEL14
SI13
SEL13
SI12
SEL12
“
“
“
“
SI1
SEL1
SI0
SEL0
13
ARINC 429 WORD SHIFT REGISTER
21
SELF
TEST
TXADIG
LINE
DRIVER
GNDA
+
TXA
ARINC 429
TRANSMITTER
TXB
GNDB
TXBDIG
12
VDD
11
10
V+
9
8
V-
7
6
DC / DC
CONVERTER
CP+
5
LBL7:0
BIT10
BIT9
4
CP-
3
CN+
2
CN-
1
GNDCONV
GND
Figure 2
HOLT INTEGRATED CIRCUITS
2
HI-8470
PIN DESCRIPTIONS
PIN
SYMBOL
FUNCTION
DESCRIPTION
1
VWET
Supply
2
SI0
Discrete Input
Sense input 0. Mapped SO0 digital output and transmitted ARINC 429 bit 11
None
3
SI1
Discrete Input
Sense input 1. Mapped SO1 digital output and transmitted ARINC 429 bit 12
None
4
SI2
Discrete Input
Sense input 2. Mapped SO2 digital output and transmitted ARINC 429 bit 13
None
5
SI3
Discrete Input
Sense input 3. Mapped SO3 digital output and transmitted ARINC 429 bit 14
None
6
SI4
Discrete Input
Sense input 4. Mapped SO4 digital output and transmitted ARINC 429 bit 15
None
7
SI5
Discrete Input
Sense input 5. Mapped SO5 digital output and transmitted ARINC 429 bit 16
None
8
SI6
Discrete Input
Sense input 6. Mapped SO6 digital output and transmitted ARINC 429 bit 17
None
9
SI7
Discrete Input
Sense input 7. Mapped SO7 digital output and transmitted ARINC 429 bit 18
None
10
SI8
Discrete Input
Sense input 8. Mapped SO8 digital output and transmitted ARINC 429 bit 19
None
11
SI9
Discrete Input
Sense input 9. Mapped SO9 digital output and transmitted ARINC 429 bit 20
None
12
SI10
Discrete Input
Sense input 10. Mapped SO10 digital output and transmitted ARINC 429 bit 21
None
13
SI11
Discrete Input
Sense input 11. Mapped SO11 digital output and transmitted ARINC 429 bit 22
None
14
SI12
Discrete Input
Sense input 12. Mapped SO12 digital output and transmitted ARINC 429 bit 23
None
15
SI13
Discrete Input
Sense input 13. Mapped SO13 digital output and transmitted ARINC 429 bit 24
None
16
SI14
Discrete Input
Sense input 14. Mapped SO14 digital output and transmitted ARINC 429 bit 25
None
17
SI15
Discrete Input
Sense input 15. Mapped SO15 digital output and transmitted ARINC 429 bit 26
None
Optional input to supply relay wetting current to Sense lines in GND/Open operation
Logic ground
PULL
UP/DOWN
-
18
GND
Supply
19
TEST0
Digital Input
When high, forces all comparator inputs to ground
30K pull-down
20
TEST1
Digital Input
When high, forces all comparator inputs high
30K pull-down
21
SO0
Digital Output
Sense channel 0 output state
-
22
SO1
Digital Output
Sense channel 1 output state
-
23
SO2
Digital Output
Sense channel 2 output state
-
24
SO3
Digital Output
Sense channel 3 output state
-
25
SO4
Digital Output
Sense channel 4 output state
-
26
SO5
Digital Output
Sense channel 5 output state
-
27
SO6
Digital Output
Sense channel 6 output state
-
28
SO7
Digital Output
Sense channel 7 output state
-
29
SO8
Digital Output
Sense channel 8 output state
-
30
SO9
Digital Output
Sense channel 9 output state
-
31
SO10
Digital Output
Sense channel 10 output state
-
32
SO11
Digital Output
Sense channel 11 output state
-
33
SO12
Digital Output
Sense channel 12 output state
-
34
SO13
Digital Output
Sense channel 13 output state
-
35
SO14
Digital Output
Sense channel 14 output state
-
36
SO15
Digital Output
Sense channel 15 output state
-
37
SPEED
Digital Input
If high ARINC 429 transmission is 100 Kbs, else 12.5 Kbs
38
MR
Digital input
Master Reset clears and initializes the transmitter. Active low.
39
CLKIN
Digital Input
1 MHZ (+/- 1%) must be provided to operate the ARINC429 transmitter
None
40
LBL0
Digital Input
Data for 8th transmitted bit of ARINC 429 word. (Label byte LSB)
None
41
LBL1
Digital input
Data for 7th transmitted bit of ARINC 429 word
None
42
LBL2
Digital input
Data for 6th transmitted bit of ARINC 429 word
None
43
LBL3
Digital input
Data for 5th transmitted bit of ARINC 429 word
None
44
LBL4
Digital input
Data for 4th transmitted bit of ARINC 429 word
None
45
LBL5
Digital input
Data for 3rd transmitted bit of ARINC 429 word
None
46
LBL6
Digital input
Data for 2nd transmitted bit of ARINC 429 word
None
47
LBL7
Digital input
Data for 1st transmitted bit of ARINC 429 word. (Label byte MSB)
None
HOLT INTEGRATED CIRCUITS
3
-
None
30K pull-up
HI-8470
PIN DESCRIPTIONS
PIN
SYMBOL
FUNCTION
DESCRIPTION
PULL UP/DOWN
48
BIT9
Digital Input
Data for 9th transmitted bit of ARINC 429 word (SDI)
None
49
BIT10
Digital Input
Data for 10th transmitted bit of ARINC 429 word (SDI)
None
50
BIT27
Digital Input
Data for 27th transmitted bit of ARINC 429 word
None
51
BIT28
Digital Input
Data for 28th transmitted bit of ARINC 429 word
None
52
BIT29
Digital Input
Data for 29th transmitted bit of ARINC 429 word
None
53
BIT30
Digital Input
Data for 30th transmitted bit of ARINC 429 word
None
54
BIT31
Digital Input
Data for 31st transmitted bit of ARINC 429 word
None
55
TMR7
Digital Input
Bit 7 of timer for automatic transmission interval selection
None
56
TMR6
Digital Input
Bit 6 of timer for automatic transmission interval selection
None
57
TMR5
Digital Input
Bit 5 of timer for automatic transmission interval selection
None
58
TMR4
Digital Input
Bit 4 of timer for automatic transmission interval selection
None
59
TMR3
Digital Input
Bit 3 of timer for automatic transmission interval selection
None
60
TMR2
Digital Input
Bit 2 of timer for automatic transmission interval selection
None
61
TMR1
Digital Input
Bit 1 of timer for automatic transmission interval selection
None
None
62
TMR0
Digital Input
Bit 0 of timer for automatic transmission interval selection
63
TXBDIG
Digital output
Logic level ARINC 429 positive signal for use with an external line driver
-
64
TXADIG
Digital output
Logic level ARINC 429 negative signal for use with an external line driver
-
65
GNDB
Supply
Lightning current return to Ground for the TXB output
-
66
TXB
Analog Output
ARINC 429 Line Driver negative output
-
67
TXA
Analog Output
ARINC 429 Line Driver positive output
-
68
GNDA
Supply
Lightning current return to Ground for the TXA output
-
69
TXENB
Digital Input
Enables automatic transmission or transmits on the positive edge
None
70
SEL0
Digital Input
If high Sense Channel 0 to be Supply/open, else GND/open
None
71
SEL1
Digital Input
If high Sense Channel 1 to be Supply/open, else GND/open
None
72
SEL2
Digital Input
If high Sense Channel 2 to be Supply/open, else GND/open
None
73
SEL3
Digital Input
If high Sense Channel 3 to be Supply/open, else GND/open
None
74
SEL4
Digital Input
If high Sense Channel 4 to be Supply/open, else GND/open
None
75
SEL5
Digital Input
If high Sense Channel 5 to be Supply/open, else GND/open
None
76
SEL6
Digital Input
If high Sense Channel 6 to be Supply/open, else GND/open
None
77
SEL7
Digital Input
If high Sense Channel 7 to be Supply/open, else GND/open
None
78
SEL8
Digital Input
If high Sense Channel 8 to be Supply/open, else GND/open
None
79
SEL9
Digital Input
If high Sense Channel 9 to be Supply/open, else GND/open
None
80
SEL10
Digital Input
If high Sense Channel 10 to be Supply/open, else GND/open
None
81
SEL11
Digital Input
If high Sense Channel 11 to be Supply/open, else GND/open
None
82
SEL12
Digital Input
If high Sense Channel 12 to be Supply/open, else GND/open
None
83
SEL13
Digital Input
If high Sense Channel 13 to be Supply/open, else GND/open
None
84
SEL14
Digital Input
If high Sense Channel 14 to be Supply/open, else GND/open
None
85
SEL15
Digital Input
If high Sense Channel 15 to be Supply/open, else GND/open
None
86
V-
Supply
If VDD=GND, attach a -6V supply, else a holding capacitor
-
87
CN+
Analog input
If VDD=GND, leave open, else a bucket capacitor plus side
-
88
CN-
Analog input
If VDD=GND, leave open, else a bucket capacitor minus side
-
89
GNDCONV
Supply
Converter and ARINC 429 Line Driver Ground
-
90
VDD
Supply
3.3V supply for DC/DC Converter and line Driver
-
91
CP-
Analog input
If VDD=GND, leave open, else a bucket capacitor minus side
-
92
CP+
Analog input
If VDD=GND, leave open, else a bucket capacitor plus side
-
93
V+
Supply
If VDD=GND, attach a +6V supply, else a holding capacitor
-
HOLT INTEGRATED CIRCUITS
4
HI-8470
PIN DESCRIPTIONS
PIN
SYMBOL
FUNCTION
DESCRIPTION
PULL UP/DOWN
94
EXTTHSOG
Digital Input
If high selects THSLOOG and THSHIOG for GND/Open thresholds,
else internal
30K pull-up
95
THSLOOG
Analog Input
Window comparator Low Threshold for GND/Open operation
-
96
THSHIOG
Analog Input
Window comparator High Threshold for GND/Open operation
-
97
EXTTHSVO
Digital Input
If high selects THSLOVG and THSHIVG for Supply/Open thresholds,
98
THSLOVO
Analog Input
Window comparator Low Threshold for Supply/Open operation
-
99
THSHIVO
Analog Input
Window comparator High Threshold for Supply/Open operation
-
100
VLOGIC
Supply
Digital Logic supply
-
else internal
30K pull-up
100 - VLOGIC
99 - THSHIVO
98 - THSLOVO
97 - EXTTHSVO
96 - THSHIOG
95 - THSLOOG
94 - EXTTHSOG
93 - V+
92 - CP+
91 - CP90 - VDD
89 - GNDCONV
88 - CN87 - CN+
86 - V85 - SEL15
84 - SEL14
83 - SEL13
82 - SEL12
81 - SEL11
80 - SEL10
79 - SEL9
78 - SEL8
77 - SEL7
76 - SEL6
PIN CONFIGURATION
- 1
- 2
- 3
- 4
- 5
- 6
- 7
- 8
- 9
- 10
- 11
- 12
- 13
- 14
- 15
- 16
- 17
- 18
- 19
- 20
- 21
- 22
- 23
- 24
- 25
HI-8470PQIF
HI-8470PQTF
75 - SEL5
74 - SEL4
73 - SEL3
72 - SEL2
71 - SEL1
70 - SEL0
69 - TXENB
68 - GNDA
67 - TXA
66 - TXB
65 - GNDB
64 - TXADIG
63 - TXBDIG
62 - TMR0
61 - TMR1
60 - TMR2
59 - TMR3
58 - TMR4
57 - TMR5
56 - TMR6
55 - TMR7
54 - BIT31
53 - BIT30
52 - BIT29
51 - BIT28
SO5 - 26
SO6 - 27
SO7 - 28
SO8 - 29
SO9 - 30
SO10 - 31
SO11 - 32
SO12 - 33
SO13 - 34
SO14 - 35
SO15 - 36
SPEED - 37
MR - 38
CLKIN - 39
LBL0 - 40
LBL1 - 41
LBL2 - 42
LBL3 - 43
LBL4 - 44
LBL5 - 45
LBL6 - 46
LBL7 - 47
BIT9 - 48
BIT10 - 49
BIT27 - 50
VWET
SI0
SI1
SI2
SI3
SI4
SI5
SI6
SI7
SI8
SI9
SI10
SI11
SI12
SI13
SI14
SI15
GND
TEST0
TEST1
SO0
SO1
SO2
SO3
SO4
100-pin Plastic Quad Flatpack (PQFP)
Figure 3
HOLT INTEGRATED CIRCUITS
5
HI-8470
FUNCTIONAL DESCRIPTION
OVERVIEW
The HI-8470 has 16 Sense channels that are individually
programmed for either GND/OPEN or SUPPLY/OPEN detection. The programming of each channel is set by strapping
the appropriate SEL pin. There are 16 SENSE INPUT pins
(SI15:0) with 16 corresponding SEL strap pins (SEL15:0).
The window comparator for detecting the state of the SENSE
INPUT is offered with a choice of either standard internal
voltage thresholds or, by option pins, the thresholds can be
supplied externally. The choice of standard internal or external thresholds is selectable for each of the two sense functions, GND/OPEN and VOLTAGE/OPEN. If an external option is chosen, there are two pins for each function to input a
HIGH or LOW level for thresholds. It is possible to set either
of the external thresholds to logic levels such that a particular
SEL option can function as digital state detection.
The HI-8470 has an onboard ARINC 429 transmitter. An onchip DC-DC converter provides 3.3V-only operation, or external +6V and -6V power supplies may be connected. This
selection is controlled by the voltage provided at the VDD
pin.
The discrete sense pins and line driver outputs are lightning
protected to RTCA/DO-160G, Section 22 Level 3 Pin
Injection Test Waveform Set A (3 & 4), Set B (3 & 5A) and Set
Z (3 & 5B) without the use of any external components.
Logic and digital inputs and outputs operate from the
VLOGIC supply.
A 1MHz clock must be provided at the CLKIN pin to operate
the ARINC 429 transmitter. The Master Reset (MR) pin is
ORed with an on-chip Power On Reset (POR).
The SPEED pin selects the speed of the ARINC 429 transmission.
When set from logic 0 to logic 1, the TXENB input pin triggers ARINC 429 word transmission. The ARINC 429 transmitter is disabled when TXENB is held at logic 0. When
TXENB is held at logic 1, periodic ARINC 429 word transmission occurs at a fixed interval programmed by eight
input pins TMR7:0. When the TMR7:0 value ranges from 1
to 255 decimal, the word re-transmit interval equals TMR
value x 10 milliseconds, or 10 to 2,550 ms.
Unique case:
When TMR7:0 equals zero, the ARINC 429 word retransmission interval depends on the state of the SPEED
input pin: For SPEED equals 0 (low-speed, 12.5Kb/s) the
shortest interval is 2.88 ms when TMR7:0 equals 0. For
SPEED equals 1 (high-speed, 100 Kb/s) the shortest retransmission interval is 360 us when TMR7:0 equals 0.
After a detected Power On Reset, transmission is disabled
for 500 ms to prevent spurious and possibly erroneous
data.
The sense data for each of the 16 channels is transmitted
directly in an ARINC 429 word. The label value is set by the
eight Label input pins (LBL7:0). 2 pins (BIT9 and BIT10)
configure the transmitted ARINC 429 SD bits. To allow
additional flexibility, the last five bits of the ARINC 429 word
are configured by the five BIT31:27 pins. Bits 11 through
26 of the ARINC 429 transmission have 16 bits of data
mapped from the SENSE INPUT detections. The 32nd bit
is odd parity. Note that the five bits of data set by the
BIT31:27 pins could alternatively be used for detection and
transmission of logic levels within the system.
Two pins (TEST1 and TEST0) provide a means of self test.
If TEST0 is taken high, all comparator inputs are forced to
ground and if TEST1 is taken high, all comparator inputs
are forced high. If both self test inputs are high, the result is
an alternating pattern with SI0 comparator input forcing a
high input, Si1 forcing a ground input, etc.
HOLT INTEGRATED CIRCUITS
6
HI-8470
FUNCTIONAL DESCRIPTION
SENSING
WETTING CURRENT
The 16 Sense Channels can be configured to meet the
requirements of a variety of conditions and applications.
Table 1 summarizes basic function selection and Table 2
gives more details on possible threshold values.
For GND/Open applications with VWET open, the wetting
current with the input voltage at GND is simply (VLOGIC 0.75)/3.3K. When applying a higher voltage at the VWET
pin the wetting current is (VLOGIC - 0.75)/3.3K + (VWET 4.2)/127K. Additional wetting current can be achieved by
placing an external resistor and a diode between VWET
and the individual sense inputs.
GND/OPEN SENSING
For GND/Open sensing, the channel’s SEL pin is connected
to GND. Referring to the Block Diagram, Figure 2, this
selection will connect a 3.3KΩ pull-up resistor through a
diode to VLOGIC and a 23.8KΩ resistor through 3 diodes to
VWET. These resistors give extra noise immunity for
detecting the open state while providing relay wetting
current. Configuring EXTTHSOG, THSHIOG, THSLOOG
and VWET as described below sets the window comparator
thresholds, VTHI and VTLO, the open input voltage when
open, and the input current.
HI-8470 THRESHOLD SELECT
The HI-8470 offers a choice between internally fixed
thresholds or external thresholds provided by the user.
With EXTTHSOG set to GND, the window comparator
thresholds are fixed based on an internal reference. The high
threshold, VTHI, and the low threshold, VTHLO levels may be
found in Table 2. When the internal references are used the
THSHIOG and THSLOOG pins should be connected to
GND.
For applications with either large GND offsets or thresholds
higher than VLOGIC - 0.75V, EXTTHSOG is set high and the
thresholds are set externally, for example by a simple
resistor divider off the VLOGIC supply. In this case VTHI is
equal to 10X the voltage on the THSHIOG pin. VTLO is equal
to 10X the voltage on the THSLOOG pin. This mode allows
the user complete flexibility to define the thresholds and
hysteresis levels.
OPEN INPUT VOLTAGE
For correct operation, the VSENSE when open, must be
higher than VTHI so SO will be low. This condition requires
VWET to be set greater than (VTHI/0.9 + 2.25V). Various
ARINC standards such as ARINC 763 define the standard
“Open” signal as characterized by a resistance of 100KΩ or
more with respect to signal ground. The user should
consider this 100KΩ to ground case when setting the
thresholds.
SUPPLY/OPEN SENSING
The 16 Sense Channels can be individually configured to
sense Supply/Open by connecting the channel’s SEL pin
to VLOGIC. Refering to Figure 2, a 32KΩ resistor is
switched in series to provide a pull down in addition the
400KΩ of the comparator input divider to GND. Similar to
the GND/Open case configuring EXTTHSVO, THSHIVO,
THSLOVO and VWET as described below sets the window comparator thresholds, the open input voltage when
open and the wetting current.
THRESHOLD SELECT
The threshold selections are handled in the same way as
stated above for the GND/OPEN case.
For EXTTHSVO set low, the internal reference nominally
sets the window comparator. See table 2 for the VTHI and
VTHLO threshold levels.
For EXTTHSVO set high, again the final thresholds are
10X the voltage set on the THSHIVO and THSLOVO pins.
The VWET pin is disconnected automatically when SEL is
high.
WETTING CURRENT
For the Supply/Open case the wetting current into the
sense input is the current sunk by the effective 28KΩ to
GND. For VSENSE_n = 28V, IWET is 1ma. See Figure 4.
Table 1. Function Table
SI
SEL
SO
Open or > VTHI
L
(GND/OPEN)
L
< VTLO
L
(GND/OPEN)
H
Open or < VTLO
H
(V+/OPEN)
H
> VThHI
H
(V+/OPEN)
L
H = VLOGIC, L = GND, X = Don’t Care, V+ = VSUPPLY
See Table 2 for values of VTHI/VTLO
HOLT INTEGRATED CIRCUITS
7
HI-8470
FUNCTIONAL DESCRIPTION
Table 2. Configuration options and allowed threshold values -55C to 125C.
VLOGIC
VWET
Pin
Operation
Threshold
Selected
Maximum
HI_SET
(VTHI =
HI_SETx10)
Minimum
LO_SET
(VTLO =
LO_SETx10)
Guaranteed
High
Threshold
Guaranteed
Low
Threshold
3.0V
OPEN
GND/OPEN
Internal
-
-
2.5V
0.8V
3.6V
OPEN
GND/OPEN
Internal
-
-
2.7V
0.8V
3.3V
28V
GND/OPEN
Internal
-
-
2.55V
0.8V
3.0V to 3.6V
7V
GND/OPEN
External
0.4V (4.0V)
0.3V (3.0V)
VTHI + 0.5V
VTLO - 0.5V
3.0V to 3.6V
28V
GND/OPEN
External
2.2V (22V)
0.3V (3.0V)
VTHI + 0.5V
VTLO - 0.5V
3.0V to 3.6V
OPEN
V+/OPEN
Internal
-
-
15.5V
11.0V
3.0V to 3.6V
OPEN
V+/OPEN
Exernal
2.2V (22V)
0.3V (3.0V)
VTHI + 0.5V
VTLO - 0.5V
NOTE: VTHI = Sense pin high threshold (HI_SET x 10), VTLO = Sense pin low threshold (LO_SET x 10)
Figure 4 Input Current Vs. Input Voltage
HOLT INTEGRATED CIRCUITS
8
HI-8470
FUNCTIONAL DESCRIPTION
ARINC 429 TRANSMITTER
ARINC 429 TRANSMITION SCHEDULING
ARINC 429 WORD ASSEMBLY
The HI-8470 outputs ARINC 429 words under the control
of the TXENB and TMR7:0 pins. Words may be output in
single-shot mode or periodically.
ARINC 429 words transmitted by the HI-8470 are formatted
as shown in Figure 5. The first eight bits transmitted are the
ARINC 429 label byte. The label value reflects the state of
pins LBL7 through LBL0 immediately prior to transmission.
ARINC 429 SD bits (bits 9 and 10) reflect the state of the
BIT9 and BIT10 pins immediately prior to transmission. The
next 19 bits comprise a discrete data field as defined in
ARINC Specification 429 Part 1, Attachment 6 “Discrete
word format”. Bits 11 through 26 reflect the state of discrete
sense pins SI0 through SI15 respectively, and bits 28 and 29
reflect the state of the BIT28 and BIT29 pins. The ARINC 429
SSM bits, bit 30 and 31 are set by input pins BIT30 and
BIT31. The last transmitted ARINC 429 bit is an odd parity
bit, which is automatically calculated by the HI-8470.
ARINC 429 BIT RATE
A 1 MHZ clock signal must be provided at the CLKIN input
pin. This clock provides the timing reference for the ARINC
429 transmitter and word scheduler.
The SPEED input pin sets the ARINC 429 transmission bit
rate and line driver slope control. When SPEED is high the
transmitter is set for ARINC 429 high-speed bit rate of 100
Kb/s and the line driver differential rise and fall time is set to
1.5 us. When SPEED is low, the bit rate is 12.5 Kb/s and the
line driver differential rise and fall time is nominally 10 us.
TXENB
Action
Pulse
width
If TXENB is held low, no ARINC 429 words are transmitted.
Pulsing TXENB high for 1-2 us causes transmission of a
single ARINC 429 word. When TXENB is held high, the
ARINC 429 words are transmitted at a periodic interval
determined by the eight TMR pins. If all TMR pins are low,
the HI-8470 transmits words at the maximum possible rate
allowed by the ARINC 429 specification. That time is equal
to 36 bit periods (32 data bits plus 4 gap times). For high
speed ARINC 429 (SPEED=1), the word interval is 360 us,
and for low-speed ARINC 429 (SPEED=0), the word
interval is 2.88 ms.
Table 5 describes TXENB function for all cases of TXENB
pulse widths and periods.
The word transmission interval may be increased in 10 ms
steps by setting the TMR7:0 to a non zero value. The
transmission interval is given by t = TMR7:0 x 10 ms
except when TMR7:0 equals 0. Example transmission
intervals are shown in Table 6.
Result
TXENB wired High
Infinite
TXENB goes high
Less than interval programmed Transmit on positive edge only
TXENB goes high
More than interval time
First transmit after POR period finished and programmed intervals thereafter
Transmit on positive edge and on each interval completion at which
TXENB remains high
TXENB goes high
Two pulses such that second
twice during transmit edge comes before ARINC
word transmitted
Transmit on first positive edge
Ignore second pulse edge and transmit again only if TXENB remains
high to interval completion
The interval is reset any time TXENB is low and starts again when TXENB goes
high
TXENB goes high
Pulse spacing wider than
twice during interval ARINC word
Transmit each edge and restart interval timer each edge
LB
L7
LB
L6
LB
L5
LB
L4
LB
L3
LB
L2
LB
L1
LB
L0
BI
T9
BI
T1
SI 0
0
SI
1
SI
2
SI
3
SI
4
SI
5
SI
6
SI
7
SI
8
SI
9
SI
10
SI
11
SI
12
SI
13
SI
14
SI
15
BI
T2
BI 7
T2
BI 8
T2
BI 9
T3
BI 0
T3
O 1
dd
Pa
rit
y
Table 5. TXENB Function Description
1
MSB
2
3
4
5
6
ARINC 429 Label
7
8
LSB
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
SD
LSB
ARINC 429 Data Field
Figure 5. ARINC 429 Word Format
HOLT INTEGRATED CIRCUITS
9
MSB
HI-8470
FUNCTIONAL DESCRIPTION
ARINC 429 LINE DRIVER
The HI-8470 includes a 3.3V single supply ARINC 429 line
driver. Internal lightning protection circuitry complies with
RTCA/DO-160 Section 22 Level 3 Pin Injection Test
Waveform Set A (3 & 4), Set B (3 & 5A) and Set Z (3 & 5B)
without external components. Pin surge levels for Level 3 are
summarized as follows:
Waveform
3
VOC/ISC
600V/24A
Waveform
4
VOC/ISC
300V/60A
Waveform
5A
VOC/ISC
300V/300A
Waveform
5B
VOC/ISC
300V/300A
The waveforms are shown in Figure 6.
An internal 37.5 Ohm resistor on each output enables direct
connection to the ARINC 429 bus.
The line driver requires only a single 3.3V power supply. An
integrated inverting / non-inverting voltage doubler
generates the rail voltages (+/- 6.6V) which are then used to
produce the +/-5V ARINC 429 output levels.
Currents for output slope control are set by on-chip
resistors. The charging current is selected by the SPEED
pin. If SPEED is high, the output rise/fall time 10% to 90%
is 1.5us. If SPEED is low, the rise and fall times are 10us.
A unity gain buffer receives the internally generated slopes
and differentially drives the ARINC line. Current is limited
by the series output resistors at each pin. There are no
fuses at the outputs of the HI-8470.
The HI-8470 has 37.5 Ohms in series with the TXA and
TXB outputs, allowing direct connection to the ARINC 429
bus. The outputs are automatically lightning protected in
compliance with RTCA/DO-160G, Section 22 Lavel 3 Pin
Injection Test Waveform Set A (3 &4), Set B (3 &5A) and
Set Z (3 & 5B) without any external components.
The HI-8470 may also be used with an external line driver,
for example when designing a system for DO-160G level 4
or higher lightning protection. The two digital outputs
directly drive the digital inputs of any stand-alone Holt
ARINC 429 line driver, such as the HI-8592 or HI-8596.
The internal dual-polarity charge pump circuit requires four
external capacitors, two capacitors for each polarity. CP+
and CP- connect the external charge transfer or “fly”
capacitor, CFLY, to the positive portion of the doubler,
resulting in twice VDD at the V+ pin. An output “hold”
capacitor, COUT, is placed between V+ and GND. COUT
should be ten times the size of CFLY. The inverting or
negative portion of the converter works in a similar fashion,
with CFLY and COUT placed between CN+/CN- and V-/GND
respectively.
SPEED TMR7:0
BIT RATE SLOPE REPETITION WORDS/
INTERVAL SECOND
0
0x00
12.5 Kb/s
10 us
2.88 ms
347.2
1
0x00
100 Kb/s
1.5 us
360 us
2,777
X
0x01
X
X
10 ms
100
X
0x05
X
X
50 ms
20
X
0x0A
X
X
100 ms
10
X
0x14
X
X
200 ms
5
X
0x32
X
X
500 ms
2
X
0x64
X
X
1s
1
X
0xC8
X
X
2s
0.5
0xFF
X
X
2.55 s
0.392
X
X = Don’t Care
Table 6. Example Transmission Schedule Rates
HOLT INTEGRATED CIRCUITS
10
HI-8470
LIGHTNING PROTECTION
The discrete sense pins and line driver outputs are lightning protected to RTCA/DO-160G, Section 22 Level 3 Pin Injection
Test Waveform Set A (3 & 4), Set B (3 & 5A) and Set Z (3 & 5B) without the use of any external components. Figures 5, 6 and 7
summarize the waveforms.
Waveform 3
Figure 5. DO-160G Lightning Induced Transient Voltage Waveform 3.
Voc = 600V, Isc = 24A, Frequency = 1MHz ± 20%.
HOLT INTEGRATED CIRCUITS
11
HI-8470
Waveform 4
Figure 6. DO-160G Lightning Induced Transient Voltage Waveform 4.
Voc = 300V, Isc = 60A.
Waveform 5
Figure 6. DO-160G Lightning Induced Transient Voltage Waveforms 5A and 5B.
Voc = 300V, Isc = 300A.
HOLT INTEGRATED CIRCUITS
12
HI-8470
RECOMMENDED
OPERATING CONDITIONS
ABSOLUTE MAXIMUM RATINGS
Voltages referenced to Ground
Supply Voltage (VLOGIC)
.........................
-0.3V to +7V
VWET
..........................
-0.3V to +50V
Max. DC Current at any pin
..................................... 125mA
Logic Input Voltage Range
................ -0.3V to VLOGIC+0.3V
Discrete Input Voltage Range
..................
Supply Voltage
VLOGIC
VWET
................................. 3.0V to 3.6V
................................. 7.0V to 36V
Operating Temperature Range
Industrial Screening ............. -40°C to +85°C
Hi-Temp Screening ............. -55°C to +125°C
-50V to +50V
Continuous Power Dissipation (TA=+70°C)
QFN (derate 21.3mW/°C above +70°C) ........
QFP (derate 10.0mW/°C above +70°C) ........
1.7W
1.5W
Solder Temperature (reflow)
260°C
..........................
Junction Temperature
.............................
175°C
Storage Temperature
............................
-65°C to -150°C
NOTE: Stresses above absolute maximum ratings or outside recommended operating conditions may cause permanent damage to the
device. These are stress ratings only. Operation at the limits is not recommended.
D.C. ELECTRICAL CHARACTERISTICS
VDD = VLOGIC = 3.3V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified).
PARAMETER
SYMBOL
CONDITION
MIN
TYP
MAX
UNITS
DISCRETE INPUTS
SENSE V+/OPEN
Resistance to Ground
SEL_n = High
RIN
Case 1: EXTTHSVO = GND
Internal Threshold Mode
Open State Input Voltage
VOS
Input voltage to give High output
V+ State Input Voltage
VV+
Input voltage to give Low output
Open State Input Current
IOS
Max input current to give High output
V+ State Input Current
IV+
Min Input current to give Low output
Input Current at 36V
Hysteresis
KΩ
30
IIN28
15.5
V
V
325
640
μA
μA
1.0
VIN = 36V
VHY
Case 2: EXTTHSVO = Open or VLOGIC
11.0
mA
1.5
V
THSHIVO/THSLOVO set Thresholds
THSHIVG Threshold Range
VHR
HI Threshold is set to THSHIHG X 10
0.4
2.2
V
THSLOVG Threshold Range
VLR
LO Threshold is set to THSLOVO X10
0.3
2.1
V
THSHIVO > THSLOVO
0.1
Min Threshold Window
10:1 Division Accuracy
VTHW
As measured by Sense Output Change
HOLT INTEGRATED CIRCUITS
13
VLR - 0.5
V
VHR + 0.5
V
HI-8470
D.C. ELECTRICAL CHARACTERISTICS (cont)
VDD = VLOGIC = 3.3V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified).
PARAMETER
SYMBOL
CONDITION
MIN
TYP
MAX
UNITS
DISCRETE INPUTS
SENSE GND/OPEN
Resistance in series with diode to VLOGIC
RIN
3.3
KΩ
Resistance in series with diode to VWET
RW
23.8
KΩ
Case 1: EXTTHSOG = GND
Internal Threshold Mode
Ground State Input Voltage
VGS
Input voltage to give High output
Open State Input Voltage
VOS
Input voltage to give Low output
VDD = 3.0V
Input Current at 0V
IIN28
VIN = 0V, VDD = 3.0V
Hysteresis
VHY
Case 2: EXTTHSOG = Open or VLOGIC
0.8
V
V
2.5
mA
-0.65
0.15
V
THSHIOG/THSLOOG pins set Thresholds
THSHIOG Threshold Range
VHR
HI Threshold is set to THSHIOG X 10
0.4
2.2
V
THSLOOG Threshold Range
VLR
LO Threshold is set to THSLOOG X 10
0.3
2.2
V
THSHIOG > THSLOOG
0.1
Min Threshold Window
VTHW
10:1 Division Accuracy
As measured by Sense Output Change
V
VHR + 0.5
VLR - 0.5
V
LOGIC INPUTS
Input Voltage
Input Current, TEST0, TEST1
VIH
Input Voltage HI
VIL
Input Votage LO
ISINK
ISOURCE
Input Current, MR, EXTTHSOG, EXTTHSVG
ISINK
ISOURCE
Input Current, SEL_n
ISINK
ISOURCE
80%
VLOGIC
20%
VIN = VLOGIC, 30KΩ pull down
VIN = VLOGIC
μA
125
0.1
VIN = GND
0.1
μA
μA
μA
125
VIN = GND , 30KΩ pull up
VLOGIC
VIN = VLOGIC
0.1
μA
VIN = GND,
0.1
μA
90%
VLOGIC
LOGIC OUTPUTS
Output Voltage
Output Current
Output Capacitance
VOH
IOH = -100μA
VOL
IOL = 100μA
IOL
VOUT= 0.4V
IOH
VOUT = VLOGIC - 0.4V
CO
10%
1.6
mA
-1.0
15
HOLT INTEGRATED CIRCUITS
14
VLOGIC
mA
pF
HI-8470
D.C. ELECTRICAL CHARACTERISTICS (cont)
VDD = VLOGIC = 3.3V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified).
PARAMETER
SYMBOL
CONDITION
MIN
TYP
MAX
UNITS
1.0
μA
ANALOG INPUTS
THSHI/THSLO Leakage Current
IL
Max leakage for VLOGIC > Vinput > GND
-0.1
LINE DRIVER OUTPUTS
No load; TXA - TXB
ARINC 429 Output Voltage (Differential)
One
Zero
Null
VDIFF1
VDIFF1
VDIFF1
ARINC 429 Output Voltage (Ref. to GND)
One or Zero
Null
VDOUT
VNOUT
ARINC 429 Output Impedance
TXA, TXB pins
ZOUT
No load & magnitude at pin
No load
9
-11
-0.5
10
-10
0
11
-9
0.5
V
V
V
4.5
-0.25
5.0
0
5.5
0.25
V
V
Ω
37.5
DC/DC CONVERTER CHARACTERISTICS
Start-up transient (V+, V-)
Operating Switching Frequency
Worst-case maximum voltage doubler
output
Ratio of bulk storage to fly-back capacitors
Fly-back capacitor
tSTART
-
-
10
ms
fSW
-
650
-
KHz
-
-
6.93
V
V+(MAX)
CFLY
CFLY(ESR)
Bulk storage capacitor
COUT
COUT(ESR)
Bypass capacitor ESR 100mΩ max.
2.2
COUT/CFLY
(Recommend multilayer ceramic, dielectric XR7 caps, 10V
min)
(Recommend multilayer ceramic, dielectric XR7 caps, 10V
min)
VDD = 3.6V. T=-55°C. Open load.
CSUPPLY
COUT/CFLY >=10
[0.5,1.0]MHz
1.0
500
4.7
μF
mΩ
COUT/CFLY >=10
[0.5,1.0]MHz
2.2
300
47
μF
mΩ
CSUPPLY>=C (connect from VDD to GND)
47
μF
(Recommend tantalum cap, 10V min)
SUPPLY
VDD Supply current
No load
Max load (400Ω)
Operating VLOGIC range
Operation VWET range
VLOGIC Current
VWET Current
IDDNL
IDDL
SPEED = 1
Continuous transmission, TMR7:0 = 0
28
65
40
mA
mA
VLOGIC
3.0
3.6
V
VWET
0
28
V
All Sense Pins Open
10
mA
All Sense Inputs = 0V, VWET = 28V
30
mA
IDD1
IVWET
HOLT INTEGRATED CIRCUITS
15
HI-8470
AC ELECTRICAL CHARACTERISTICS
VDD = 3.3V, GND = 0V, TA = Operating Temperature Range (unless otherwise specified).
PARAMETER
SYMBOL
CONDITION
MIN
TYP
MAX
UNITS
SENSE V+/OPEN
Delay, Output going High
tH1
1.0
μs
Delay, Output going Low
tL1
1.0
μs
Delay, Output going High
tH2
1.0
μs
Delay, Output going Low
tL2
1.0
μs
SENSE GND/OPEN
LINE DRIVER
Line Driver Transistion Times
High Speed (SPEED = 1)
Output high to low
tFX1
1.0
1.5
2.0
μs
Output low to high
tRX1
1.0
1.5
2.0
μs
Output high to low
tFX2
5.0
10.0
15.0
μs
Output low to high
tRX2
5.0
10.0
15.0
μs
Low Speed (SPEED = 0)
CLOCK (CLKIN)
Clock frequency for ARINC 429 compliance
fCLKIN
HOLT INTEGRATED CIRCUITS
16
1.0 +/- 1%
MHZ
HI-8470
ORDERING INFORMATION
HI - 8470PQ x F
LEAD
FINISH
PART
NUMBER
100% Matte Tin (Pb-free, RoHS compliant)
F
PART
NUMBER
TEMPERATURE
RANGE
FLOW
BURN
IN
I
-40°C TO +85°C
I
NO
T
-55°C TO +125°C
T
NO
PART
NUMBER
PACKAGE
DESCRIPTION
8470PQ
100 PIN PLASTIC QUAD FLATPACK (PQFP)
HOLT INTEGRATED CIRCUITS
17
HI-8470
REVISION HISTORY
P/N
Rev
DS8470 A
Date
5/31/13
Description of Change
Changed maximum ground state input voltage for ground detection from 1.0V to 0.8V.
Corrected typo for V+ state input voltage in DC Characteristics from 15.0V to 15.5V.
Changed maximum wetting current from 20mA to 30mA.
HOLT INTEGRATED CIRCUITS
18
PACKAGE DIMENSIONS
inches (millimeters)
100-PIN PLASTIC QUAD FLAT PACK (PQFP)
Package Type: 100PQS
.020 BSC
(0.50)
.630
BSC SQ
(16.0)
.551
BSC SQ
(14.0)
.009 ± .002
(.22 ± .05)
.024 ± .006
(.60 ± .15)
.039
typ
(1.0)
See Detail A
.063 max.
(1.60)
.008 min
(0.20)
.008 R max
(0.20)
.055 ± .002
(1.40 ± .05)
0° £ Q £ 7°
BSC = “Basic Spacing between Centers”
is theoretical true position dimension and
has no tolerance. (JEDEC Standard 95)
.003 R min
(0.08)
HOLT INTEGRATED CIRCUITS
19
Detail A