*sIPO 104

Waiting for data

Signal	Value
Signal	Value

Cursor 1	Cursor 2	∆X	1/∆X	∆Y	∆Y (Phase)

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

Out of date
V	—
V	—
V_PP	—
V_RMS	—
V_AV	—
f_V	—
I	—
I	—
I_PP	—
I_RMS	—
I_AV	—
f_I	—
D	—

ID:

x10

x0.1

Sheet:1

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Circuit Details

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SPICE

SPICE Netlist

This is a text-based representation of the circuit.
The * symbol indicates a comment.
The + symbol indicates a continuation from the previous line.
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** sIPO 104 **
*
* Multisim Live SPICE netlist
*
*

* --- Circuit Topology ---

* Component: DG1
aDG1 1 Digital_Source_DG1

* Component: DG2
aDG2 5 Digital_Source_DG2

* Component: LED1
xLED1 2 0 LED_VIRTUAL_LED1

* Component: LED2
xLED2 3 0 LED_VIRTUAL_LED2

* Component: LED3
xLED3 4 0 LED_VIRTUAL_LED3

* Component: LED4
xLED4 6 0 LED_VIRTUAL_LED4

* Component: U1
xU1 1 5 U1_NC_SET bridgeU1!RESET bridgeU1!Q U1_NC_~Q Digital_DFlipFlop_U1 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Rise_delay=1e-9 Fall_delay=1e-9 Clk_delay=1e-9 Set_delay=1e-9 Reset_delay=1e-9 Ic=0

xbridgeU1!RESET bridgeU1!RESET 0 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU1!Q bridgeU1!Q 2 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* Component: U2
xU2 bridgeU2!D 5 U2_NC_SET bridgeU2!RESET bridgeU2!Q U2_NC_~Q Digital_DFlipFlop_U2 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Rise_delay=1e-9 Fall_delay=1e-9 Clk_delay=1e-9 Set_delay=1e-9 Reset_delay=1e-9 Ic=0

xbridgeU2!D bridgeU2!D 2 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU2!RESET bridgeU2!RESET 0 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU2!Q bridgeU2!Q 3 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* Component: U3
xU3 bridgeU3!D 5 U3_NC_SET bridgeU3!RESET bridgeU3!Q U3_NC_~Q Digital_DFlipFlop_U3 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Rise_delay=1e-9 Fall_delay=1e-9 Clk_delay=1e-9 Set_delay=1e-9 Reset_delay=1e-9 Ic=0

xbridgeU3!D bridgeU3!D 3 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU3!RESET bridgeU3!RESET 0 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU3!Q bridgeU3!Q 4 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* Component: U4
xU4 bridgeU4!D 5 U4_NC_SET bridgeU4!RESET bridgeU4!Q U4_NC_~Q Digital_DFlipFlop_U4 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Rise_delay=1e-9 Fall_delay=1e-9 Clk_delay=1e-9 Set_delay=1e-9 Reset_delay=1e-9 Ic=0

xbridgeU4!D bridgeU4!D 4 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU4!RESET bridgeU4!RESET 0 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

xbridgeU4!Q bridgeU4!Q 6 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* --- Circuit Models ---

* DG1 model
.model Digital_Source_DG1 d_constsource(State=1)

* DG2 model
.model Digital_Source_DG2 d_constsource(State=1)

* --- Subcircuits ---

* LED1 subcircuit
.subckt LED_VIRTUAL_LED1 A K

dd1 A 0vNode ledDiodeModel
.model ledDiodeModel D( IS=1e-14 N=1 RS=0 IBV=1e-10 BV=1e+30 CJO=0 M=0.5 VJ=1 )

V_Isense 0vNode K DC 0

* Interactive sense node
b1 lit 0 v = { if (i(V_Isense) < 0, 0, if( i(V_Isense) > 0.005, 1, { i(V_Isense) / 0.005 })) }

.ends

* LED2 subcircuit
.subckt LED_VIRTUAL_LED2 A K

dd1 A 0vNode ledDiodeModel
.model ledDiodeModel D( IS=1e-14 N=1 RS=0 IBV=1e-10 BV=1e+30 CJO=0 M=0.5 VJ=1 )

V_Isense 0vNode K DC 0

* Interactive sense node
b1 lit 0 v = { if (i(V_Isense) < 0, 0, if( i(V_Isense) > 0.005, 1, { i(V_Isense) / 0.005 })) }

.ends

* LED3 subcircuit
.subckt LED_VIRTUAL_LED3 A K

dd1 A 0vNode ledDiodeModel
.model ledDiodeModel D( IS=1e-14 N=1 RS=0 IBV=1e-10 BV=1e+30 CJO=0 M=0.5 VJ=1 )

V_Isense 0vNode K DC 0

* Interactive sense node
b1 lit 0 v = { if (i(V_Isense) < 0, 0, if( i(V_Isense) > 0.005, 1, { i(V_Isense) / 0.005 })) }

.ends

* LED4 subcircuit
.subckt LED_VIRTUAL_LED4 A K

dd1 A 0vNode ledDiodeModel
.model ledDiodeModel D( IS=1e-14 N=1 RS=0 IBV=1e-10 BV=1e+30 CJO=0 M=0.5 VJ=1 )

V_Isense 0vNode K DC 0

* Interactive sense node
b1 lit 0 v = { if (i(V_Isense) < 0, 0, if( i(V_Isense) > 0.005, 1, { i(V_Isense) / 0.005 })) }

.ends

* U1 subcircuit
.subckt Digital_DFlipFlop_U1 1 2 3 4 5 6 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Clk_delay=1n Set_delay=1n Reset_delay=1n Ic=0 Rise_delay=1n Fall_delay=1n
*PIN MAPPING: D Q ~Q RESET CLK SET
* 1 5 6 4 2 3
*MODELS USED
aDG1 neg_SR Digital_SourceSR
aDG2 neg_clk Digital_SourceCLK
Axor1 [3 neg_SR] set xor
Axor2 [2 neg_clk] clk xor
Axor3 [4 neg_SR] reset xor
Ajkff 1 clk set reset 5 6 D_FF

.model Digital_SourceCLK d_constsource(State={Negative_Edge_Clock})
.model Digital_SourceSR d_constsource(State={Negative_SET_RESET})
.model xor d_xor
.MODEL D_FF d_dff (clk_delay={Clk_delay} set_delay={Set_delay} reset_delay={Reset_delay} ic={Ic} rise_delay={Rise_delay} fall_delay={Fall_delay})
.ENDS

* U2 subcircuit
.subckt Digital_DFlipFlop_U2 1 2 3 4 5 6 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Clk_delay=1n Set_delay=1n Reset_delay=1n Ic=0 Rise_delay=1n Fall_delay=1n
*PIN MAPPING: D Q ~Q RESET CLK SET
* 1 5 6 4 2 3
*MODELS USED
aDG1 neg_SR Digital_SourceSR
aDG2 neg_clk Digital_SourceCLK
Axor1 [3 neg_SR] set xor
Axor2 [2 neg_clk] clk xor
Axor3 [4 neg_SR] reset xor
Ajkff 1 clk set reset 5 6 D_FF

.model Digital_SourceCLK d_constsource(State={Negative_Edge_Clock})
.model Digital_SourceSR d_constsource(State={Negative_SET_RESET})
.model xor d_xor
.MODEL D_FF d_dff (clk_delay={Clk_delay} set_delay={Set_delay} reset_delay={Reset_delay} ic={Ic} rise_delay={Rise_delay} fall_delay={Fall_delay})
.ENDS

* U3 subcircuit
.subckt Digital_DFlipFlop_U3 1 2 3 4 5 6 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Clk_delay=1n Set_delay=1n Reset_delay=1n Ic=0 Rise_delay=1n Fall_delay=1n
*PIN MAPPING: D Q ~Q RESET CLK SET
* 1 5 6 4 2 3
*MODELS USED
aDG1 neg_SR Digital_SourceSR
aDG2 neg_clk Digital_SourceCLK
Axor1 [3 neg_SR] set xor
Axor2 [2 neg_clk] clk xor
Axor3 [4 neg_SR] reset xor
Ajkff 1 clk set reset 5 6 D_FF

.model Digital_SourceCLK d_constsource(State={Negative_Edge_Clock})
.model Digital_SourceSR d_constsource(State={Negative_SET_RESET})
.model xor d_xor
.MODEL D_FF d_dff (clk_delay={Clk_delay} set_delay={Set_delay} reset_delay={Reset_delay} ic={Ic} rise_delay={Rise_delay} fall_delay={Fall_delay})
.ENDS

* U4 subcircuit
.subckt Digital_DFlipFlop_U4 1 2 3 4 5 6 PARAMS: Negative_Edge_Clock=0 Negative_SET_RESET=0 Clk_delay=1n Set_delay=1n Reset_delay=1n Ic=0 Rise_delay=1n Fall_delay=1n
*PIN MAPPING: D Q ~Q RESET CLK SET
* 1 5 6 4 2 3
*MODELS USED
aDG1 neg_SR Digital_SourceSR
aDG2 neg_clk Digital_SourceCLK
Axor1 [3 neg_SR] set xor
Axor2 [2 neg_clk] clk xor
Axor3 [4 neg_SR] reset xor
Ajkff 1 clk set reset 5 6 D_FF

.model Digital_SourceCLK d_constsource(State={Negative_Edge_Clock})
.model Digital_SourceSR d_constsource(State={Negative_SET_RESET})
.model xor d_xor
.MODEL D_FF d_dff (clk_delay={Clk_delay} set_delay={Set_delay} reset_delay={Reset_delay} ic={Ic} rise_delay={Rise_delay} fall_delay={Fall_delay})
.ENDS

* --- Pin bridge models

.SUBCKT REAL_CUSTOM_ADC 1 2 PARAMS: lowV=0 maxLowV=0.8 unknownV=1.0 minHighV=2.0 highV=5.0 riseT=0 fallT=0
* Ideal Receiver Model 1 = input, 2 = A/D out
aADCin1 [2] [1] ADC
.MODEL ADC adc_bridge (in_low = {maxLowV} in_high = {minHighV})
.ENDS

.SUBCKT REAL_CUSTOM_DAC 1 2 PARAMS: lowV=0 maxLowV=0.8 unknownV=1.0 minHighV=2.0 highV=5.0 riseT=0 fallT=0
* Ideal Driver Model 1 = A/D out, 2 = input
aDACin1 [1] [2] aDAC
.MODEL aDAC dac_bridge (out_low = {lowV} out_high = {highV} out_undef = {unknownV} t_rise = {max(riseT,1e-9)} t_fall = {max(fallT,1e-9)})
.ENDS

Errors and Warnings

Any error, warning or information messages appear below.

Item

Document

Section

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Type

Rise time

Time it takes for signal to transition from low to high.

With non-zero rise time, the signal converts to an analog signal from a digital signal.

Fall time

Time it takes for signal to transition from high to low.

With non-zero fall time, the signal converts to an analog signal from a digital signal.

Use document settings

Use logic levels settings from Document tab.

Threshold voltage levels.

Threshold voltage values used in the logic evaluation. See Digital Simulation for more information.

Output low

Output low voltage.

Maximum output voltage level to produce a low signal.

Input low threshold

Input low threshold voltage.

Maximum input voltage level for the signal to be considered low.

Input high threshold

Input high threshold voltage.

Minimum input voltage level for the signal to be considered high.

Output high

Output high voltage.

Minimum output voltage level to produce a high signal.

Type Probe

Select desired function.

Function

Use document settings

Use logic levels settings from Document tab.

Threshold voltage levels.

Threshold voltage values used in the logic evaluation. See Digital Simulation for more information.

Output low

Output low voltage.

Maximum output voltage level to produce a low signal.

Input low threshold

Input low threshold voltage.

Maximum input voltage level for the signal to be considered low.

Input high threshold

Input high threshold voltage.

Minimum input voltage level for the signal to be considered high.

Output high

Output high voltage.

Minimum output voltage level to produce a high signal.

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Source

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Instantaneous

Displays instantaneous measurements on probe during interactive simulation.

Periodic

Displays periodic measurements on probe during Interactive simulation.

Bias point(s)

Displays bias points on probe for DC Op simulation.

Name

Type

Name sIPO 104

Type Schematic

The simulation to run. See Simulation types for more information.

Name

Title of graph. Edit as desired.

End time

Time at which the simulation stops. Does not include pauses. Simulation does not occur in real time.

Start simulation

RELTOL

Relative error tolerance. A simulation wide accuracy control used to establish convergence.

VNTOL

Absolute voltage error tolerance. Defines the minimum value for voltage where it may still be considered accurate.

ABSTOL

Absolute current error tolerance. Defines the minimum value for current where it may still be considered accurate.

ITL1

DC iteration limit. Number of iterative passes done on DC circuit equations in attempt to reach convergence in simulation.

ITL4

Upper iteration limit. Number of iterative passes done per time point, on Transient circuit equations in attempt to reach convergence in simulation.

Integration method. The numerical integration method used in transient analysis.

Temp

℃

Operating temperature. The temperature at which the entire circuit will be simulated.

Insert shunt resistance

Inserts a resistance of RSHUNT from every analog node to ground. Will aid in convergence, but alter the behavior of the circuit.

RSHUNT

Shunt resistance. This eliminates singular matrix errors that result from a lack of a DC path to ground.

Reset to default

Threshold voltage levels.

Threshold voltage values used in the logic evaluation. See Digital Simulation for more information.

Output low

Output low voltage.

Maximum output voltage level to produce a low signal.

Input low threshold

Input low threshold voltage.

Maximum input voltage level for the signal to be considered low.

Input high threshold

Input high threshold voltage.

Minimum input voltage level for the signal to be considered high.

Output high

Output high voltage.

Minimum output voltage level to produce a high signal.

Width

Sheet width in grid squares.

Height

Sheet height in grid squares.

Grid

Toggles grid display.

Net Labels

Toggles all net labels.

Component Labels

Toggles all component labels.

sIPO 104