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General Specifications GS J08X0-0E FX Series Computing Units (Variable Software Type) Moving Average Unit, Dead Time Unit, Velocity Unit, First Order Lug Unit, First Order Lead Unit, Velocity Limiter, Peak Holder, Bottom Holder, Analog Memory, Program Setter, Limiter, Linearizer, Temperature Compensator, Pressure Compensator, Adder/Subtractor, Multiplier, Divider, High Selector, Low Selector, Programmable Unit General The JUXTA FX Series, Computing unit (Variable Software Type) receives voltage input signals, applies various computing functions to them, and outputs isolated DC current or DC voltage signals to controllers or recorders. The computation parameters, zero points, and spans can be set and modified using a Handy Terminal (JHT00). List of Computing Units Moving Average Unit Dead Time Unit Velocity Unit First Order Lug Unit First Order Lead Unit Velocity Limiter Table. List of FX Series Descriptions Peak Holder (with second input for holding) Bottom Holder (with second input for holding) Analog Memory (with second input for holding) Program Setter (with the input for commands) Limiter Linearizer Temperature Compensator Pressure Compensator Adder/Subtractor Multiplier Divider High Selector Low Selector Programmable Unit Models : V or A FX-MA FX-DT FX-VC FX-LG FX-LE FX-VL FX-PH FX-BH FX-AM FX-PS FX-LM FX-FX FX-TR FX-PR FX-AS FX-ML FX-DV FX-HS FX-LS FX-FP Model and Suffix Codes FX--*B Model (See Table ) A: Current signal V: Voltage signal Function (See Table ) : Voltage signal 0: Custom order (Current signal) See Table [Model FXA] [Model FXV] A: to 0 ma DC : 0 to 0 mv DC B: to 0 ma DC : 0 to 00 mv DC C: to ma DC : 0 to V DC D: 0 to 0 ma DC : 0 to 0 V DC E: 0 to ma DC : 0 to V DC F: 0 to 0 ma DC : to V DC G: 0 to ma DC : -0 to +0 V DC Z: (Custom order) 0: (Custom order) Current signal Voltage signal See Table See Table Power supply V DC±0% Ordering Information Specify the following when ordering. If the fixed constants for each computing function are specified with the order, the specified values will be assigned before shipment. If not specified, the products are shipped with factory default settings. (Refer to Functions for other items which need to be specified when ordering.) Model and suffix codes: e.g. FXA-MA-A*B range: e.g. to V DC Moving average time: e.g. 0 sec. Yokogawa Electric Corporation -9-, Nakacho, Musashino-shi, Tokyo, 80-80 Japan Tel.: 8---9 Fax.: 8---9 GS J08X0-0E Copyright Mar. 00(YK) nd Edition Aug. 0, 00(YK)

Specificatons signal: Refer to Table signal point of DC voltage signal points of DC voltage signals Table. Signals Model and Suffix codes FX-MA, FX-DT, FX-VC, FX-LG, FX-LE, FX-VL, FX-PS, FX-LM, FX-FX FX-PH, FX-BH, FX-AM, FX-TR, FX-PR, FX-AS, FX-ML, FX-DV, FX-HS, FX-LS, FX-FP Measuring range: Refer to Table signal DC voltage signal Table. Measuring Range Measuring range Specify within 0 to 0 V DC when voltage is applied (Span: V or more) resistance: MΩ (00 kω or more during power off) Maximum allowable input: - to + V DC adjustment function: ±% of span (Zero/Span) Specifications signal: DC current signal or DC voltage signal Allowable load resistance: Refer to Table range Table. Signals range to 0 ma DC: 0 Ω or less 0 to 0 mv DC: 0 kω or more to 0 ma DC: 00 Ω or less 0 to 00 mv DC: 0 kω or more to ma DC: 000 Ω or less 0 to V DC: kω or more 0 to 0 ma DC: 0 Ω or less 0 to 0 V DC: 0 kω or more 0 to ma DC: 900 Ω or less 0 to V DC: kω or more 0 to 0 ma DC: 00 Ω or less to V DC: kω or more 0 to ma DC: kω or less -0 to +0 V DC: 0 kω or more adjustment function: ±% of span (Zero/Span) Standard Performance Accuracy rating: ±0.% of span, excepting the computing units noted below. Note that the accuracy is not guaranteed for output levels less than 0.% of the span of 0 to X ma output range type. FX-FX: ±0.% of span (when piecewise-linear-gain is or less) FX-TR, FX-PR: ±0.% of span (when K=K=, A=0%, and X=00%) FX-AS: ±0.% of span (when K=K=, K=0., A=A=A=0%) FX-ML: ±0.% of span (when K=K=K=, A=A=A=0%) FX-DV: ±0.% of span (when K=K=K=, A=A=A=0%) FX-FP: ±0.% of span (when ; %=; %) Response speed: 00 ms, % response (0 to 90%) Computation cycle: 00 ms Insulation resistance: 00 MΩ or more at 00 V DC between input and output, output and power supply, and input and power supply. Withstand voltage: 00 V AC/min. between (input and output) and power supply. 00 V AC/min. between output and power supply. Environmental Conditions Operating temperature range: 0 to 0 C Operating humidity range: to 90% RH (no condensation) Power supply voltage: V DC±0% Effect of power supply voltage fluctuations: ±0.% or less of span for fluctuation of V DC±0% Effect of ambient temperature change: ±0.% of span or less for a temperature change of 0 C. Current consumption: V DC 0 ma (FXV), 8 ma (FXA) Mounting and Dimensions Material: ABS resin (Case body) Mounting method: Rack, Wall, or DIN rail mounting Connection: M screw terminal External dimensions: x x mm (H x W x D) Weight: Approx.0 g Standard Accessories Tag number label: Range label: Mounting block: Mounting screw: M screw x Custom Order Specifications signal: DC current signal - Refer to Table resistance x ( curent) shall be within the measuring span of voltage input signal. Table. Acceptable Range for Signals signal resistance signal 0 to 0 ma DC 00 Ω 0 to 0 ma DC 0 Ω to 0 ma DC 0 Ω 0 to ma DC 0 Ω to 0 ma DC 00 Ω 0 to 0 ma DC 00 Ω to ma DC kω 0 to ma DC kω signal: Refer to Table resistance Table. Acceptable Range for Signals Current signal Voltage signal range 0 to ma DC -0 to +0 V DC Span to ma DC 0 mv to 0 V DC Zero elevation 0 to 00% -00 to +00% All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

Terminal Assignments FX-MA, -DT, -VC, -LG, -LE, -VL, -LM, -FX Do not use this terminal (+) (-) (+) (-) Power supply (+) Power supply (-) FX-PS Start/Reset Do not use this terminal Start/Reset (+) (-) Power supply (+) Power supply (-) FX-PH, -BH, -AM, -TR, -PR, -AS, -ML, -DV, -HS, -LS, -FP /Hold (+) (+), /Hold (-) (+) (-) Power supply (+) Power supply (-) Block Diagrams FX -MA, -DT, -VC, -LG, -LE, -VL, -LM, -FX Handy Terminal (JHT00) or PC-Based Parameter Setting Tool (VJ) Communication Interface Microprocessor Insulation circuit Low drift input processing circuit Computation Zero adjustment Span adjustment circuit Power supply circuit Power supply FX -PS Handy Terminal (JHT00) or PC-Based Parameter Setting Tool (VJ) Communication lnterface Microprocessor Insulation circuit Start/Reset Low drift input processing circuit Computation Zero adjustment Span adjustment circuit Power supply circuit Power supply FX -PH, -BH, -AM, -TR, -AS, -ML, -DV, -HS, -LS, -FP Handy Terminal (JHT00) or PC-Based Parameter Setting Tool (VJ) /Hold Communication Interface Microprocessor Computation Low drift input Zero adjustment processing circuit Span adjustment Insulation circuit circuit Power supply circuit Power supply All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

Functions FX-MA Moving Average Unit This computing unit outputs the average of 0 input data (X) sampled at intervals of one-twentieth of the moving-average time (L). At the next sampling, the unit discards the oldest data and outputs the average of the 0 data, repeating the same operation. The output between samplings is smoothed out by interpolation. X+X+...X0 Moving average (Y) = 0 X 0 X 9 X 8 X X X Computation time X X X X X Time Setting range of moving average time: 0 to 990 sec. with significant digits. minimum unit is sec. To use a first order lag filter for input (X), set the first order lag time constant (T). Setting range of time constant: 0.0 to 99.0 sec.; minimum unit is 0. sec. Accuracy of moving average and time constant setting: (±.0% of set value) ± sec. Moving average time: factory default; 0 sec. First order lag time constant: factory default; 0 sec. FX-DT Dead Time Unit This computing unit stores the input values (X) sampled at intervals of one-twentieth of the dead time (L) into 0 buffers and outputs data (Y) by orderly shifting them after the dead time has elapsed. The output between samplings is smoothed by interpolation. Y= e -LS +TS X X:, L: Dead time Y:, T: Time constant <Example: 0% 00% step input> Setting range of dead time: 0 to 990 sec. with significant digits. minimum unit is sec. To use a first order lag filter for input (X), set the first order lag time constant (T). Setting range of time constant: 0.0 to 99.0 sec.; minimum unit is 0. sec. Accuracy of dead time and time constant setting: (±.0% of set value) ± sec. Dead time: factory default; 0 sec. First order lag time constant: factory default; 0 sec. L FX-VC Velocity Unit This computing unit calculates the input velocity by subtracting the input of the last velocity computation (X L ) from the present input (X). The unit then adds a 0% bias to one-half of the obtained velocity and outputs the result (Y). The output obtained is as follows: When there is no change in input: 0% When the input has increased: 0% or more (00% when X-X L = 00%) When the input has decreased: 0% or less (0% when X-X L = -00%) Y= X-X L + 0% X: Present X L: of the last velocity computation Y: 00% 0% 00% 0% Computation cycle Setting range of velocity computation time: 0 to 990 sec. with significant digits. minimum unit is sec. To use a first-order lag filter for input (X), set the first order lag time constant (T). Setting range of time constant: 0.0 to 99.0 sec.; minimum unit is 0. sec. Accuracy of velocity computation and time constant setting: (±.0% of set value) ± sec. Velocity computation time (L): factory default; 0 sec. First order lag time constant (T): factory default; 0 sec. FX-LG First Order Lag Unit This computing unit provides a first-order lag computation on input (X) with a time constant (T) and outputs the result (Y). Y= +TS X X:, T S : Time constant, Y: <Example: 0% 00% step input> 0%.% 0% 00% 00% Setting range of time constant:.0 to 99.0 sec.; minimum unit is 0. sec. Accuracy of time constant setting: (±.0% of set value) ± sec. First order lag time constant: factory default; 0 sec. T All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

FX-LE First Order Lead Unit This computing unit provides a first order lead computation on input (X) with a time constant (T) and outputs the result (Y). TS Y=(+ +TS ) X X:, T S : Time constant, Y: <Example: 0% 0% step input> 0% 8.% 0% T 0% 00% 0% Setting range of time constant:.0 to 99.0 sec.; minimum unit is 0. second. Accuracy of time constant setting: (±.0% of set value) ± sec. First-order lead time constant: factory default; 0 sec. FX-VL Velocity Limiter This computing unit limits the input (X) velocity at the ascending velocity limit for a positive change, at the descending velocity limit for a negative change, and outputs the limited value (Y). When the input velocity (slope) is not more than the limit, the unit outputs the input as it is. <Example: 0% 00% 0% step input> 0% 0% Ascending velocity limit (%/min.) 00% 00% Descending velocity limit (%/min.) Setting range of velocity limit: 0. to 00.0%/min.; minimum unit is 0. %/min. Setting the limit at 00.0%/min. or above does not limit the input, the unit simply outputs the input as is (Open limit function). Setting accuracy of velocity limit: (±.0% of set value) ± 0.%/min. Ascending velocity limit: factory default; 00%/min. Descending velocity limit: factory default; 00%/min. FX-PH Peak Holder This computing unit outputs the current signal or voltage signal (Y) corresponding to the peak value when receiving hold-command input of more than %. FX-AM Analog Memory This computing unit holds the output signal (Y) at the moment when receiving hold-command input of more than %. FX-PS Program Setter This computing unit starts the program when start/reset command input of more than % is accepted, and outputs the isolated current or voltage signal internally generated. The output signal changes with the time lapse corresponding to the time table breakpoints. Setting conditions of time table: 0.0 sec. (t 0 to t 0 ) 98 sec., -0.0% (Y 0 to Y 0 ) 0.0% t 0 < t < t < t < t < t < t < t < t 8 < t 9 < t 0 Time breakpoints: t 0 to t 0 breakpoints: Y 0 to Y 0 Setting resolution: Time; 8 sec., s; 0.% OUT Time Time table: Write and specify all data of t0 to t0 and Y0 to Y0 on the work sheet below. <Work Sheet> Model and suffix code: Time (second) (%) t0 Y0 t Y t Y t Y t Y t Y t Y t Y t8 Y8 t9 Y9 t0 Y0 FX-BH Bottom Holder This computing unit outputs the current signal or voltage signal (Y) corresponding to the bottom value when receiving hold-command input of more than %. All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

FX-LM Limiter This computing unit serves as an ordinary computing unit as long as the input (X) is within the upper and lower limits. When the input exceeds the limit, the unit outputs the signal that corresponds to the limit (Y). Setting range of limit: within 0.0 to 00.0%; minimum unit is 0.% (both upper and lower) However, if the upper limit is set less than the lower limit, the unit outputs the upper limit. OUT IN Upper limit: factory default; 00% Lower limit: factory default; 0% FX-FX Linearizer This computing unit gives an arbitrary relationship between the input (X) and output (Y) signals using an arbitrary piecewise linear function. This piecewise linear function has breakpoints, which each give an input-output relationship as a percentage (%). Breakpoint setting conditions: -0.0% (X 0 to X 0 ) 0.0%, -0.0% (Y 0 to Y 0 ) 0.0% X 0 < X <X < X < X < X < X < X < X 8 < X 9 < X0 breakpoints: X 0 to X 0 breakpoints: Y 0 to Y 0 OUT FX-TR Temperature Compensator This computing unit performs temperature compensation to gas flow signals (X) and temperature signals (X) measured by pressure flowmeters (Orifice, Bentury, Flow nozzle, etc.), and outputs the compensated gas flow signal (Y). Computing parameters can be set using Handy Terminals. For the standard specification, the input signals are DC voltage signals within the span (V or more). Formula Y= K X K X+A Y: Compensated flow output (%) X: Uncompensated flow input (%) X: Temperature input (%) K: Gain (no unit) K: Gain (no unit) A: Bias (%) If square root extraction is necessary for uncompensated flow input signal, set store address for the fixed constant (value of C). With square root extraction: C=00.0% Without square root extraction: C=0.0% gain ±.990, bias ±99.0% = ±99.0% minimum unit; gain 0.00, bias 0.%. Gain: factory default; K=K=.000 Bias: factory default; A=0.0% Square root extraction for flow input: factory default; no setting How to obtain the gain (K, K) and bias (A): Uncompensated flow input span K= Compensated flow input span Breakpoint data: factory default; = Note: When specifying the data, write all data of X0 to X0 and Y0 to Y0 on the work sheet below. <Work Sheet> Model and suffix code: X0 X X X X X X X X8 X9 X0 (%) (%) Y0 Y Y Y Y Y Y Y Y8 Y9 Y0 Temperature input span (K) K = Reference temperature (K) A = Max. value (ºC) Min. value(ºc) (of temperature range) = Reference temperature (ºC) +. (ºC) Min. value (K) (of temperature range) Reference temperature (K) X 00 (%) Min. value (ºC) (of temperature range) +. (ºC) = X 00 (%) Reference temperature ( C) +. (ºC) Note: Use Divider in cases where the temperature compensation for gas flow is measured by vortex flowmeter. All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

FX-PR Pressure Compensator This computing unit performs temperature compensation to gas flow signal (X) and pressure signal (X) measured by pressure flowmeters (Orifice, Bentury, Flow nozzle, etc.), and outputs the compensated gas flow signal (Y). Computing parameters can be set using Handy Terminals. For the standard specification, the input signals are DC voltage signals within the span (V or more). Formula Y= K X K X+A Y: Compensated flow output (%) X: Uncompensated flow input (%) X: Pressure input (%) K: Gain (no unit) K: Gain (no unit) A: Bias (%) If square root extraction is necessary for uncompensated flow input signal (X), set store address for the fixed constant (value of C). With square root extraction: C=00.0% Without square root extraction: C=0.0% gain ±.990, bias ±99.0% = ±99.0% minimum unit; gain 0.00, bias 0.%. Gain: factory default; K=K=.000 Bias: factory default; A=0.0% Square root extraction for flow input: factory default; no setting How to obtain the gain (K, K) and bias (A): K= Uncompensated flow input span Compensated flow input span FX-AS Adder/Subtractor (X, X) from various converters, and outputs the isolated current or voltage signal (Y) after addition and subtraction. Formula: Y=K{K(X+A)+K(X+A)}+A Y: (%) K to K: Gain (no unit) X, X: (%) A to A: Bias (%) gain ±.990, bias ±99.0% = ±99.0% Gain: factory default; K=K=K=.000 Bias: factory default; A=A=A=0.0% FX-ML Multiplier (X, X) from various converters, and outputs the isolated current or voltage signal (Y) after multiplication. The unit can perform pressure compensation by inputting gas flow signal measured by vortex flowmeter etc. and pressure signal as two input signals. Formula: Y=K(K X+A) (K X+A)+A Y: (%) K to K: Gain (no unit) X, X: (%) A to A: Bias (%) gain ±.990, bias ±99.0% = ±99.0% Gain: factory default; K=K=K=.000 Bias: factory default; A=A=A=0.0% How to obtain the gain (K, K, K) and bias (A, A, A) for pressure compensation: 8 K= Max. value (kpa) Min. value (kpa) (of pressure transmitter range) Reference pressure (kpa) + 0. (kpa) K= since the output value of flow transmitter is A=0% since the output value of flow transmitter is Min. value (kpa) + 0. (kpa) (of pressure transmitter range) A= X 00 (%) Reference pressure (kpa) + 0. (kpa) Note: Use Divider in cases where the temperature compensation for gas flow is measured by vortex flowmeter. K= Max. value (kpa) Min. value (kpa) (of pressure transmitter range) Reference pressure (kpa) + 0. (kpa) Min. value (kpa) + 0. (kpa) (of pressure transmitter range) A= X 00 (%) Reference pressure (kpa) + 0. (kpa) K= Uncompensated flow input span Compensated flow input span A=0% since the compensated flow value is normally Note: Use Pressure compensator in cases where the pressure compensation for gas flow is measured by pressure flowmeter. All Rights Reserved. Copyright 00, Yokogawa Electric Corporation GS J08X0-0E Aug. 0, 00-00

FX-DV Divider (X, X) from various converters, and outputs the isolated current or voltage signal (Y) after division. The unit can perform temperature compensation by inputting gas flow signal measured by vortex flowmeter etc.and temperatue signal as two input signals. Formula: FX-FP Programmable Unit (X, X) from various converters, performs various computations and outputs the isolated current or voltage signal as the result. 9 K (K X+A) Y = K X+A +A Y: (%) K to K: Gain (no unit) X, X: (%) A to A: Bias (%) gain ±.990, bias ±99.0% = ±99.0% Gain: factory default; K=K=K=.000 Bias: factory default; A=A=A=0.0% How to obtain the gain (K, K, K) and bias (A, A, A) for temperature compensation: K= since the output value of flow transmitter is A=0% since the output value of flow transmitter is Temperature input span (K) K= Reference temperature (K) Max. value ( C) Min. value ( C) (of temperature range) = Reference temperature ºC +. ( C) A = Min. value (K) (of temperature range) Reference temperature (K) X 00 (%) Min. value (ºC) (of temperature range) +. (ºC) = X 00 (%) Reference temperature ( C) +. (ºC) K= Uncompensated flow input span Compensated flow input span A=0% since the compensated flow value is normally Note: Use Temperature compensator in cases where the temperature compensation for gas flow is measured by pressure flowmeter. FX-HS High Selector (X, X) from various converters, selects the higher one (Y), and outputs a current signal or a voltage signal. FX-LS Low Selector (X, X) from various converters, selects the lower one (Y), and outputs a current signal or a voltage signal. All Rights Reserved. Copyright 00, Yokogawa Electric Corporation Subject to change without notice. GS J08X0-0E Aug. 0, 00-00