XTR108EA-2K5 BURR-BROWN [Burr-Brown Corporation], XTR108EA-2K5 Datasheet - Page 18

XTR108EA-2K5

Manufacturer Part Number

XTR108EA-2K5

Description

Manufacturer

BURR-BROWN [Burr-Brown Corporation]

Datasheet

1.XTR108EA-2K5.pdf (32 pages)

Current page: 18 of 32
Download datasheet (902Kb)

EEPROM DATA STORAGE

The XTR108 automatically reads data from an SPI-compat-

ible EEPROM device. The models 25C040 from MicroChip

and the AT25010 from Atmel have been tested and are

known to work. Equivalent devices with an SPI interface can

be expected to work. The XTR108 will read data from

addresses 4 through 15 of the EEPROM. The address in the

EEPROM is the same as the address for the corresponding

data in the XTR108. The XTR108 will not write data to the

EEPROM. The external calibration controller is responsible

for writing data to the EEPROM.

CHECKSUM FUNCTION

To validate the data from the EEPROM device, the XTR108

calculates a checksum on the incoming serial-data stream

during each write operation. The value written to the EEPROM

that will be transferred to register 15 during an EEPROM read

operation must be such that the sum of the data in registers 4

through 15 totals 0xFF (255). The sum is calculated by

performing an add/accumulate function on all of the data

bytes of a read operation. An end-around carry is used during

the add/accumulate operation. If a carry-out was generated in

the previous add operation, it is used as a carry-in for the next

add operation for the checksum operation. The following code

shows how the value of register 15 could be calculated:

For a test or calibration operation, it may be necessary to

write to a few select registers. This may be accomplished

without writing to register 15. To accomplish this, write to

the necessary registers and release CS1. There is no need to

update register 15.

If the command is to disable the automatic read-back func-

tion by setting the RDB bit in register 4, it is necessary to

rewrite the entire register set data with a correct checksum

value in register 15. The automatic read-back mode will be

disabled upon successful checksum operation.

The checksum error flag is also cleared when the XTR108

is reset (i.e.: at power ON). Write operations that do not

write to the checksum register will have no effect on the

checksum error flag. By locating the checksum register after

the last configuration register and including the checksum

by the checksum function.

EEPROM DATA SECURITY

Since the data in the EEPROM directly affects the analog

output of the XTR108, the data in the EEPROM needs to be

secure from accidental write operations. SPI EEPROM de-

vices have a write-protect function on one of the pins. An

additional connection to the calibration controller would be

required if the write-protect pin is used to prevent accidental

write operations. SPI EEPROM devices require a special

Sum = 0

FOR Index = 4 TO 14

NEXT Index

Data [15] = 255 – Sum

Sum = Sum + Data [Index]

IF Sum > 255 THEN

Sum = Sum – 255

www.ti.com

write enable instruction to be executed to write data to the

EEPROM. It is unlikely that this would accidentally be

written to the EEPROM device and then be followed by a

valid write operation. Further security can be obtained by

using an SPI EEPROM device that has internal write-protect

control bits. These bits are nonvolatile and must be cleared

before write operations are allowed.

SURGE PROTECTION

Remote connections to current transmitters can sometimes

be subjected to voltage surges. It is prudent to limit the

maximum surge voltage applied to the XTR108 with various

zener diodes and surge-clamping diodes specially designed

for this purpose. Since the maximum voltage on the XTR108

loop is limited by the external MOSFET breakdown voltage,

usually more than 200V, the requirement to the clamping

devices are not very strict. For example, a 50V protection

diode will assure proper transmitter operation at normal loop

voltages without significant leakage yet provide an appro-

priate level of protection against voltage surges. In case of

prolonged (seconds and longer) overvoltage, lower voltage

clamps may be used to limit the power dissipation on the

transmitter.

Most surge-protection zener diodes have a diode character-

istic in the forward direction that will conduct excessive

current, possibly damaging receiving-side circuitry if the

loop connections are reversed. If a surge protection diode is

used, a series diode or diode bridge should be used for

protection against reversed connections.

REVERSE-VOLTAGE PROTECTION

The XTR108’s low compliance rating (7.5V) permits the

use of various voltage protection methods without compro-

mising operating range. Figure 8 shows a diode bridge

circuit which allows normal operation even when the volt-

age connection lines are reversed. The bridge causes a two

diode drop (approximately 1.4V) loss in loop supply volt-

age. This results in a compliance voltage of approximately

9V—satisfactory for most applications. If 1.4V drop in loop

supply is too much, a diode can be inserted in series with the

loop supply voltage and the V+ pin. This protects against

reverse output connection lines with only a 0.7V loss in loop

supply voltage.

RADIO FREQUENCY INTERFERENCE

The long wire lengths of current loops invite radio frequency

interference. RF energy can be rectified by the sensitive

input circuitry of the XTR108 causing errors. This generally

appears as an unstable output current that varies with the

position of loop supply or input wiring.

If the RTD sensor is remotely located, the interference may

enter at the input terminals. For integrated transmitter as-

semblies with short connection to the sensor, the interfer-

ence more likely comes from the current loop connections.

Bypass capacitors on the input reduce or eliminate this input

interference. Connect these bypass capacitors to the I

terminal, see Figure 9. Although the DC voltage at the I

terminal is not equal to 0V (at the loop supply, V

circuit point can be considered the transmitter’s “ground.”

The 0.01 F capacitor connected between V

help minimize output interference.

LOOP

and I

XTR108

SBOS187C

) this

may

RET

XTR108EA-2K5 BURR-BROWN [Burr-Brown Corporation], XTR108EA-2K5 Datasheet - Page 18

XTR108EA-2K5

Related parts for XTR108EA-2K5