ETC 77LD1-12K240-02

PC-77LD1
APEX Signal, A Division of NAI, Inc.
TWELVE (12) LVDT-TO-DIGITAL CONVERTERS
“PROGRAMMABLE” TRACKING CONVERTERS
FEATURES:
•
•
•
•
•
•
•
•
•
•
•
•
•
16-bit resolution
0.025% FS accuracy
Continuous background BIT testing with Excitation and Signal loss detection
Self-calibrating. Does not require removal for calibration
360 Hz to 10 kHz operation
Autoranging input between 2.0 and 28 Vrms
12, 8, and 4-channel versions available
Optional programmable reference excitation
Transformer isolated
LATCH feature
Compensates for ±60° phase shift
No adjustments or trimming required
Part Number, S/N, Date Code, and Revision in permanent memory
DESCRIPTION:
This high-density intelligent DSP-based card incorporates up to twelve (12) separate transformer isolated
programmable LVDT/RVDT-to-Digital tracking converters with extensive diagnostics, and optional programmable
excitation supply. Instead of buying cards that are set for specific inputs, the uniqueness of this design makes it
possible to order our standard card that auto-ranges between 2.0 and 28 volts. Operating frequency between 400 Hz
and 10 kHz can be specified. Each chanel is programmable for either 2 wire or 3,4 wire inputs. For 2 wire inputs, the
output is computed as A/B (where A is the LVDT output and B is the excitation) and is expressed as % FS. For 3 or
4-wire devices, the output is computed as A-B/A+B and is expressed as %FS. This ratiometric technique assures
that the output will change only when the LVDT position changes and will ignore excitation voltage variations. The
LATCH feature permits the user to read all channels at the same time. Reading will unlatch that channel. The
converters utilize a Type II servo loop processing technique that enables tracking, at full accuracy, up to the specified
maximum rate. Intermediate transparent latches, on all data and velocity outputs, guarantee that current valid data is
always available for any channel, without affecting the tracking performance of the converters. The optional on−board
excitation is field programmable. To simplify logistics, Part Number, S/N, Date Code, and Revision are stored in
permanent memory locations.
This board incorporates major diagnostics that offer substantial improvements to system reliability because user is
alerted to channel malfunction. Three different tests (one on-line and two off-line) can be selected:
The D2 Test initiates automatic background BIT testing. Each channel is checked over the programmed Signal
range to a measuring accuracy 0.1% FS, and each Signal and Excitation is monitored. Results are available in
registers. The testing is totally transparent to the user, requires no external programming, has no effect on the
standard operation of this card and can be enabled or disabled via the bus.
The D3 Test, if enabled, starts an initiated BIT test that disconnects all channels from the outside world and connects
them across an internal stimulus that generates and measures multiple voltages to a test accuracy of 0.1%FS.
External excitation is not required. Results can be read from registers. The testing requires no external programming
and can be initiated or terminated via the bus.
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 1 of 7
The D0 Test is used to check the card and the PCbus interface. All channels are disconnected from the outside
world, allowing the user to write any number of input positions to the card and then read the data from the interface.
External excitation is not required.
SPECIFICATIONS:
Number of channels:
Resolution:
Accuracy:
Bandwidth:
Input format:
Input voltage
Excitation voltage:
Input Impedance:
Frequency:
Phase shift:
Wrap around Self Test:
Power:
Temperature, operating:
Storage temperature:
Weight:
EXCITATION:
Voltage:
Frequency:
Regulation:
Output power:
4, 8, or 12 (see part number)
16-bit
0.025% FS
10% of excitation to 100 Hz max. BW and tracking rate can easily be customized.
LVDT or RVDT
Autoranging from 2.0 to 28 Vrms. Transformer isolated.
Not required for computation of output but should be connected to allow card to
check for excitation loss.
40 kΩ min. at 360 Hz
Specify between 360 Hz to 10 kHz, (See Part Number)
Automatically compensates for phase shifts between the transducer excitation and
output up to ±60° (3 or 4-wire units ignore phase shift)
Three powerful test methods are described in the Programming Instructions.
+ 5 VDC at 0.35 A
±12 VDC at 0.1 A without Excitation; 1.1 A for 5 VA Excitation Output
0°C to +70°C
-45°C to +85°C.
20 oz.
Optional (See part number).
2.0-28 Vrms programmable (resolution 0.1 Vrms) or 115 Vrms fixed. Accuracy ±2%.
360 Hz to 10 kHz ±1% with 1 Hz resolution.
10% max., no load to full load.
5 VA max. at 40° min. inductive.
Principals of LVDT Operation : Typically, the LVDT primary is excited by an ac source, causing a magnetic flux
to be generated within the transducer. Voltages are induced in the two secondaries, with the magnitude varying with
the position of the core. Usually, the secondaries are connected in series opposition, causing a net output voltage of
zero when the core is at the electrical center. When the core is displaced in either direction from center, the voltage
increases linearly either in phase or out of phase with the excitation depending on the direction.
Interfacing the LVDT to the Converter
Two common connection methods are:
1. Primary as reference (two-wire system)
This method of connection converts the widest range of LVDT sensors and. is the most sensitive to excitation
voltage variations, as well as temperature and phase shift effects.
2. Derived reference (three/four-wire LVDT)
The LVDT is again excited from the primary side, but the converter reference is the sum of A + B that has
constant amplitude for changing core displacement. This system is insensitive to temperature effects, phase
shifts and oscillator instability and solves the identity (A-B)/(A+B)
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 2 of 7
(IN-PHASE)
(USUAL LVDT CONFIGURATION)
10.0 V
Example uses
10Vrms output
Vb
5.0 V
Va
0.0 V
POSITION
-FS
O
+FS
Va+Vb=10V Va+Vb=10V Va+Vb=10V
Va-Vb=10V Va-Vb=0V
Va-Vb=10V
Va=0V
Va=5V
Va=10V
Vb=10V
Vb=5V
Vb=0V
Various LDVT configurations
4 WIRE
32WIRE
WIRE
B
B
A-B
A
-B
A+B
A
EXCITATION
A
EXCITATION
EXCITATION
A
3 WIRE
B
A-B
A+B
LVDT Connections:
For 3,4 Wire LVDT’s, connect A and B LVDT outputs to Signal A and B inputs. Excitation is not used but should be
connected to enable card to sense and report any excitation loss.
For 2 Wire LVDT’s, connect A-B output of LVDT to card “A” input and connect external excitation voltage to card “B”
input and excitation input.
PROGRAMMING INSTRUCTIONS:
I/O CONFIGURATION:
This card requires 32 consecutive addresses in the I/O address space on a 32 byte boundary. The base
address is switch settable in the 000-3E0 hex (0 to 992) address range.
ADDRESS= BASE + OFFSET
BASE
A9
A8
A7
A6
A5
OFFSET A4, A3, A2, A1, A0
SW1*
SW2∗
SW3∗
SW4∗
SW5∗
∗ “1” = Off “0” = On
Decimal equiv.
32
64
128
256
512
NOTE: Base addresses to avoid:
378-37F Parallel Printer Port 3B0-3BF Monochrome Display 3F8-3FF Asynch Comm
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
3F0-3F7
Floppy Disk
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 3 of 7
Page 1 (Offset 1E = 0)
00
01
02
03
04
05
06
Ch.1Lo
Ch.1 Hi
Ch.2 Lo
Ch.2 Hi
Ch.3 Lo
Ch.3 Hi
Ch.4Lo
read
read
read
read
read
read
read
07
08
09
0A
0B
0C
0D
Ch.4 Hi
Ch.5 Lo
Ch.5 Hi
Ch.6 Lo
Ch.6 Hi
Ch.7 Lo
Ch.7 Hi
read
read
read
read
read
read
read
0E
0F
10
11
12
13
14
Ch. 8 Lo
Ch. 8 Hi
Ch. 9 Lo
Ch. 9 Hi
Ch.10 Lo
Ch.10 Hi
Ch.11 Lo
read
read
read
read
read
read
read
15
16
17
18
19
1A
1B
Ch.11 Hi
Ch.12 Lo
Ch.12 Hi
Status, Signal loss Lo
Status, Signal loss Hi
Status, Exc. Loss Lo
Status, Exc. Loss Hi
read 1C Status, Test Lo
read 1D Status, Test Hi
read 1E Page register = 0
read
read
read
read
read
read
write
Page 2 (Offset 1E = 1)
00
01
02
03
04
05
06
Sig. Ch.1 Lo
Sig. Ch.1 Hi
Sig. Ch.2 Lo
Sig. Ch.2 Hi
Sig. Ch.3 Lo
Sig. Ch.3 Hi
Sig. Ch.4 Lo
write/read
write/read
write/read
write/read
write/read
write/read
write/read
07
08
09
0A
0B
0C
0D
Sig. Ch.4 Hi
Sig. Ch.5 Lo
Sig. Ch.5 Hi
Sig. Ch.6 Lo
Sig. Ch.6 Hi
Sig. Ch.7 Lo
Sig. Ch.7 Hi
07
08
09
0A
0B
0C
0D
(A+B) Ch.4 Hi
(A+B) Ch.5 Lo
(A+B) Ch.5 Hi
(A+B) Ch.6 Lo
(A+B) Ch.6 Hi
(A+B) Ch.7 Lo
(A+B) Ch.7 Hi
write/read
write/read
write/read
write/read
write/read
write/read
write/read
0E
0F
10
11
12
13
14
Sig. Ch.8 Lo
Sig. Ch.8 Hi
Sig. Ch.9 Lo
Sig. Ch.9 Hi
Sig. Ch.10 Lo
Sig. Ch.10 Hi
Sig. Ch.11 Lo
read
read
read
read
read
read
read
0E
0F
10
11
12
13
14
(A+B) Ch.8 Lo
(A+B) Ch.8 Hi
(A+B) Ch. 9 Lo
(A+B) Ch. 9 Hi
(A+B) Ch.10 Lo
(A+B) Ch.10 Hi
(A+B) Ch.11 Lo
write/read
write/read
write/read
write/read
write/read
write/read
write/read
15
16
17
1E
Sig. Ch.11 Hi
write/read
Sig. Ch.12 Lo
write/read
Sig. Ch.12 Hi
write/read
Page register = 1
write
read
read
read
read
read
read
read
15
16
17
1E
(A+B) Ch.11 Hi
(A+B) Ch.12 Lo
(A+B) Ch.12 Hi
Page register = 5
Page 6 (Offset 1E = 5)
00
01
02
03
04
05
06
(A+B) Ch.1 Lo
(A+B) Ch.1 Hi
(A+B) Ch.2 Lo
(A+B) Ch.2 Hi
(A+B) Ch.3 Lo
(A+B) Ch.3 Hi
(A+B) Ch.4 Lo
read
read
read
read
read
read
read
read
read
read
write
Page 7 (Offset 1E = 6)
00 Enable, Test
02 Test (D2) verify
06 Test position Lo
write/read 07 Test position Hiread/write 0C Eo Lo byte
write/read 0A Freq. Lo byte read/write 0D Eo Hi byte
read/write 0B Freq. Hi byte read/write 0E Active Ch. Lo
read/write
read/write
read/write
0F
10
14
1E
Active Ch. Hi
2or 3,4 wire input
Latch
Page register = 6
read/wr
write
write
Page 8 (Offset 1E = 7)
00 Save
0E P/N
write 0F P/N Hi
read 10 Date code Lo
read 11 Date code Hi read 13 Rev. level Hi
read 12 Rev. level Lo read 14 S/N Lo
Hi byte
Latch outputs
Test Enable
Active channels
Status, signal
Status, excitation
Status, Test
2 or 3,4 wire Input
read 15 S/N Hi
read
read 1E Page register = 7
Lo byte
D15
D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Ch.12
Ch.12
Ch.12
Ch.12
Ch.12
X
X
Ch.11
Ch.11
Ch.11
Ch.11
Ch.11
X
X
Ch.10
Ch.10
Ch.10
Ch.10
Ch.10
X
X
Ch.9
Ch.9
Ch.9
Ch.9
Ch.9
X
X
Ch.8
Ch.8
Ch.8
Ch.8
Ch.8
X
X
Ch.7
Ch.7
Ch.7
Ch.7
Ch.7
X
X
Ch.6
Ch.6
Ch.6
Ch.6
Ch.6
X
X
Ch.5
Ch.5
Ch.5
Ch.5
Ch.5
X
D3
Ch.4
Ch.4
Ch.4
Ch.4
Ch.4
X
D2
Ch.3
Ch.3
Ch.3
Ch.3
Ch.3
1
X
Ch.2
Ch.2
Ch.2
Ch.2
Ch.2
X
D0
Ch.1
Ch.1
Ch.1
Ch.1
Ch.1
At Power-On or System Reset, all parameters are restored to last saved setup.
Enter Active Channels: Set the bit, corresponding to each channel to be monitored during BIT testing, in the
Active Channel Register at page 7, 0Eh/0Fh. “1”=active; “0”=not used. Omitting this step will produce false alarms
because unused channels will set faults.
Save Setup: The current setup can be saved by writing 5555h to the Save Register at page 8, 00/01h. This
location will automatically clear to 00/01h when the save is completed (within 5 seconds). When save is elected, all
parameters are saved, however, any parameter can be changed at will. Saving is optional. If not saved, reenter
parameters at each power up.
To restore factory shipped parameters, write AAAAh to the Save Register at page 8, 00/01h, followed by System
Reset. Note: After a SAVE or RESTORE, poll page 8, 00h and do not perform any other operation until word is at
"0".
Data Format: The output data is A-B/A+B and represents %FS. Format is two's complement. Max. positive
excursion is 7FFF, 0 = 0, and max. negative excursion is 8000.
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 4 of 7
Signal and Reference
The LVDT primary is energized by either the on-board excitation or from an external excitation. The 4-wire or 3-wire
LVDT has two output voltages referred to as A and B. When connected to the A and B Signal inputs no scaling is
required because the inputs are autoranging, however the Signal registers can be used to scale the output code.
Default settings for the Signal Registers at page 2 are FFFFh. This results in a full scale output reading for full travel
of the LVDT. A full scale output reading for less than full travel of the LVDT can be programmed by writing to the
Signal Registers on page 2. For example, writing 8000h to page 2, 00/01h will result in channel 1 having a full scale
output reading for one-half travel of the LVDT.
For 2 wire Inputs, the Signal register can be used to adjust what fraction of the excitation voltage represents “full
travel” of the LVDT.
Optional Reference Supply: For frequency, write a 16-bit word ( ex: 400 Hz = 1 1001 0000) at Page 7,
OAh/OBh. For voltage, write a word ( ex: 26.1 Vrms = 1 0000 0101) with LSB = 0.1 Vrms, to address Page 7,
OCh/ODh . It is recommended that the user program the required frequency before setting the output voltage.
Selecting 2 or 3,4 Wire operation: Program the proper channel in the appropriate register on page 7,10h.
Logic 1 = 2 wire and logic 0 = 3,4 wire.
Read (A+B) output:: Read binary number at appropriate register on page 6, and multiply by 0.01 Volt. For 2 wire
Inputs, this represents the B voltage.
Latch: All channels may be latched by writing “1” to D1 at Page 7, 14h. Reading channel will disengage latch.
D2 Test Enable: Writing “1” to D2 at page 7, 00h initiates automatic background BIT testing. Each channel is
checked over the programmed Signal range to a measuring accuracy 0.1%FS, and each Signal and Excitation is
monitored. The results are available in Status Registers. The testing is totally transparent to the user,
requires no external programming, has no effect on the standard operation of this card and can be enabled or
disabled via the bus. The card will write 55h to page 7, 02h when D2 is enabled. User can periodically clear to
0000h and then read page 7, 02h again, after 30 seconds, to verify that background BIT testing is activated.
Status, Test: Check the corresponding bit of the Test Status Register at page 1, 1Ch/1Dh for status of BIT testing
for each active channel. A ”1” = Accuracy OK; “0” = failed. (test cycle takes 45 seconds for accuracy error).
Status, Exc: Check the corresponding bit of the Exc Status Register at page 1, 1AH/1Bh for status of the
excitation input for each active channel. A ”1” = Exc. ON, “0” = Exc. Loss (Excitation loss is detected after 2
seconds).
Status, Sig: Check the corresponding bit of the Sig Status Register at page 1, 18h/19h for status of the input
signals for each active channel. A "1" = Signal ON, “0” = Signal loss (Signal loss is detected after 2 seconds).
D3 Test Enable: Writing “1” to D3 of Test Register at page7, 00h, initiates a BIT test that disconnects all channels
from the outside world and connects them across an internal stimulus that generates multiple test voltages that are
measured to a test accuracy of 0.1%FS. Test cycle takes about 45 seconds and results can be read from the Status
Registers when D3 changes from “1” to “0”. External excitation is not required. Testing requires no external
programming and can be initiated or terminated (by setting D3 to “0”) via the bus.
D0 Test Enable: Checks the card and the PCbus interface. Writing “1” to D0 at page 7, 00h disconnects all
channels from the outside world, allowing user to write any number of input positions to the card at page 7 06/07h
and then read the data from the PCbus interface (allow 400 ms after writing). External excitation is not required.
NOTE: The DO test will follow the program of channel 1: if channel 1 is programmed for 2 wire, then all channels will
be tested in the 2 wire mode. If channel 1 is programmed for 3,4 wire, then all channels will be tested in the 3,4 wire
mode.
If the card is set up as a mix of 2 and 3,4 wire channels, then chan 1 must be set as 2 wire (and all channels will be
tested with the appropriate channels passing ) and then chan 1 set as 3,4 wire ( and all channels will be tested with
the appropriate channels passing ).
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 5 of 7
Front panel Connector: J1
AMP 748483-5
Pin
39
78
58
19
38
77
Ch.1
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Mate: AMP 748368-1
Pin Ch.2
18 Sig. A Lo
57 Sig. A Hi
76 Sig. B Hi
37 Sig. B Lo
17 Exc. Hi
56 Exc. Lo
Pin
36
75
55
16
35
74
Pin Ch.11
Pin Ch.12
24 Sig. A Lo
Sig. A Hi
43 Sig. B Hi
4 Sig. B Lo
23 Exc. Hi
62 Exc. Lo
3
42
61
22
2
41
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Ch.3
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin
15
54
73
34
14
53
Ch.4
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin
33
72
52
13
32
71
Ch.5
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin
12
51
70
31
11
50
Ch.6
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin
30
69
49
10
29
68
Ch.7
Pin
Sig. A Lo 9
Sig. A Hi 48
Sig. B Hi 67
Sig. B Lo 28
Exc. Hi
8
Exc. Lo 47
Ch.8
Pin Ch.9
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
27
66
46
7
26
65
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin Ch.10
6
45
64
25
5
44
Sig. A Lo
Sig. A Hi
Sig. B Hi
Sig. B Lo
Exc. Hi
Exc. Lo
Pin
Latch +
59
Latch20
1 & 40 Chassis
21
60
Int. Exc. Out Hi
Int. Exc. Out Lo
Do not connect to any undesignated pins.
CAUTION:
The male mating connector can have dangerous voltages on the pins. Be certain that power is
turned off before removing the connector.
Code Table
Code
01
02
03
04
05
Frequency (Hz) Notes
400
2.8k - 3.2k
2k
2.69k
3k
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 6 of 7
PART NUMBER DESIGNATION
77LD1 - XX X X X X - XX
TOTAL NUMBER OF CHANNELS
04 = 4 Channels
08 = 8 Channels
12 = 12 Channels
ENVIRONMENTAL
C = No Conformal Coating
K = Removable Conformal Coating
ISA BUS
1 = 8-Bit ISA Bus
2 = 16-Bit ISA Bus
Apex Signal, A Division of NAI, Inc.
170 Wilbur Place, Bohemia, NY, 11716,USA
CODE (See Code Table)
OPTIONS
0 = None
9 = Custom Design (See Separate Spec)
EXCITATION
With On-Board Excitation Supply:
1 = One Common Excitation Input Tied
to the Excitation Supply
2 = Individual Excitation Inputs
Without On-Board Excitation Supply
3 = One Common Excitation Input
4 = Individual Excitation Inputs
631.567.1100/631.567.1823(fax)
www.naii.com / e-mail:[email protected]
1-31-01
Code:OVGU1
S 77 LD1 A001 REV B 1.2
Page 7 of 7