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D Q ~Q RESET CLK SET D Q ~Q RESET CLK SET D Q ~Q RESET CLK SET D Q ~Q RESET CLK SET 1010 U1U2U3U4InputCLK120LED130PR1PR2PR3LED2PR4LED3PR5LED4PR6405060 0/1 0/1 0/1 0/1 0/1 0/1
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ID:

ID:

x10
x0.1
Sheet:1
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SPICE Netlist

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** 9b **
*
* Multisim Live SPICE netlist
*
*

* --- Circuit Topology ---

* Component: CLK
aCLK 2 Digital_Source_CLK

* Component: Input
aInput 1 Digital_Source_Input

* Component: LED1
xLED1 3 0 LED_VIRTUAL_LED1

* Component: LED2
xLED2 6 0 LED_VIRTUAL_LED2

* Component: LED3
xLED3 5 0 LED_VIRTUAL_LED3

* Component: LED4
xLED4 4 0 LED_VIRTUAL_LED4

* Component: U1
xU1 bridgeU1!D 2 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!D bridgeU1!D 3 REAL_CUSTOM_ADC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=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 6 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* Component: U2
xU2 1 2 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!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 2 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 6 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 5 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0

* Component: U4
xU4 bridgeU4!D 2 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 5 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 4 REAL_CUSTOM_DAC PARAMS: lowV=0 maxLowV=0.8 unknownV=1 minHighV=2 highV=5 riseT=0 fallT=0


* --- Circuit Models ---

* CLK model
.model Digital_Source_CLK d_constsource(State=1)

* Input model
.model Digital_Source_Input 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
VHDL Netlist

This is a text-based representation of a digital circuit.
The -- symbols indicates a comment.
Probes and analog components do not appear in VHDL netlists.

-- This is a VHDL representation of the -- digital circuit described in the schematic. -- If the circuit described is not valid or is incomplete, -- it may result in an invalid VHDL representation. library IEEE; use IEEE.STD_LOGIC_1164.ALL; USE WORK.ALL; entity top_design is Port ( ); end top_design; architecture BEHAVIORAL of top_design is begin end BEHAVIORAL;
Errors and Warnings

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TypeDescription
A component update replaced the symbol for component U1 with a newer version. Check your schematic.
A component update replaced the symbol for component U2 with a newer version. Check your schematic.
A component update replaced the symbol for component U3 with a newer version. Check your schematic.
A component update replaced the symbol for component U4 with a newer version. Check your schematic.
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9b
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V

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V

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

Input high threshold

V

Input high threshold voltage.

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

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Output high voltage.

Minimum output voltage level to produce a high signal.

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