Difference between revisions of "Ngspice Tutorial"
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== Classes Using this Tutorial == | == Classes Using this Tutorial == | ||
− | * [ | + | * [[CoE 197U]] Introduction to Analog and Digital Integrated Circuit Design |
+ | * [[EE 220]] Analog Integrated Circuits | ||
== Installing ngspice == | == Installing ngspice == | ||
Line 18: | Line 19: | ||
This is the [https://github.com/louisalarcon/eee51_tutorials/blob/master/tutorials/circuit1.sp netlist] for the circuit in Figure 1: | This is the [https://github.com/louisalarcon/eee51_tutorials/blob/master/tutorials/circuit1.sp netlist] for the circuit in Figure 1: | ||
− | <source lang=" | + | <source lang="bash" line> |
* Transistor Characteristic Curves | * Transistor Characteristic Curves | ||
* LPA 2020-04-16 | * LPA 2020-04-16 | ||
Line 45: | Line 46: | ||
SPICE “dot commands” are commands that provide directives to the simulator. These are the commands in lines 4, 5, 11, 17, and 19. | SPICE “dot commands” are commands that provide directives to the simulator. These are the commands in lines 4, 5, 11, 17, and 19. | ||
− | * The <code>.include <filename></code> command includes other files, such as those that contain model information. In this case, <code>.include 2N2222A.lib</code> (line 4) adds the [http://www.onsemi.com/pub/Collateral/2N2222A.LIB.TXT model file] for a transistor, the [http://web.mit.edu/6.101/www/reference/2N2222A.pdf 2N2222A] NPN BJT. | + | * The <code>.include <filename></code> command includes other files, such as those that contain model information. In this case, <code>.include 2N2222A.lib</code> (line 4) adds the [http://www.onsemi.com/pub/Collateral/2N2222A.LIB.TXT model file] for a transistor, the [http://web.mit.edu/6.101/www/reference/2N2222A.pdf 2N2222A] NPN BJT. When you download the model file, make sure you rename it correctly<ref group=fn>The original model file name has a '''.TXT''' extension that, depending on your system, could be hidden.</ref>. |
* The <code>.options savecurrents</code> (line 5) command tells the simulator to save the current data, since by default, only voltage data is saved. | * The <code>.options savecurrents</code> (line 5) command tells the simulator to save the current data, since by default, only voltage data is saved. | ||
* The <code>.control</code> and <code>.endc</code> encapsulate the control statements, which specify which analyses will be performed by the simulator. | * The <code>.control</code> and <code>.endc</code> encapsulate the control statements, which specify which analyses will be performed by the simulator. | ||
Line 52: | Line 53: | ||
The main part of the netlist is the list of devices together with the nodes where the terminals of these devices are connected to. | The main part of the netlist is the list of devices together with the nodes where the terminals of these devices are connected to. | ||
− | * Line 7 instantiates a BJT with format <code>Qxxx <collector node> <base node> <emitter node> <model name></code> | + | * Line 7 instantiates a BJT with format: |
− | + | ** <code>Qxxx <collector node> <base node> <emitter node> <model name></code> | |
+ | ** The instance name of a BJT always starts with a '''Q''', and is followed by the names of the nodes connected to its collector, base, and emitter. You can choose the names of the nodes. Note that, by convention, node '''0''' is the ground node. The model name is the name given in the model file. | ||
− | Analysis Statements are placed inside the control block, and specify which analysis needs to be performed. Line 13 tells the simulator to perform a DC Analysis, i.e. sweep a source voltage or current and determine the behavior of the circuit. In this case, the simulator will vary '''Vbe''' from 500mV to 750mV in steps of 1mV. A DC analysis can be invoked by <code>dc <source> <start> <stop> <step></code> | + | * Lines 8 and 9 instantiate the voltage sources '''Vbe''' and '''Vce''' using: |
+ | ** <code>Vxxx <pos> <neg> <parameters></code> | ||
+ | ** In this case, '''Vbe''' and '''Vce''' are both ideal DC voltage sources with values 0.0V and 0.2V respectively. | ||
+ | |||
+ | Analysis Statements are placed inside the control block, and specify which analysis needs to be performed. Line 13 tells the simulator to perform a DC Analysis, i.e. sweep a source voltage or current and determine the behavior of the circuit. In this case, the simulator will vary '''Vbe''' from 500mV to 750mV in steps of 1mV. A DC analysis can be invoked by: | ||
+ | * <code>dc <independent source> <start> <stop> <step></code> | ||
Line 15 instructs the simulator to write the collector current data of transistor '''Q1''' (using the '@' directive) to a file named '''circuit1.dat.''' | Line 15 instructs the simulator to write the collector current data of transistor '''Q1''' (using the '@' directive) to a file named '''circuit1.dat.''' | ||
Line 62: | Line 69: | ||
== Running the Simulation == | == Running the Simulation == | ||
− | The simulator can be invoked by running | + | The simulator can be invoked by running <code>ngspice</code> from the command line. This brings up the simulator in interactive mode, and you are presented with a prompt: |
<source lang="text"> | <source lang="text"> | ||
Line 74: | Line 81: | ||
ngspice 1 -> | ngspice 1 -> | ||
</source> | </source> | ||
+ | |||
+ | To run the simulator, type in the command <code>source circuit1.sp</code>: | ||
+ | |||
+ | <source lang="text"> | ||
+ | ngspice 1 -> source circuit1.sp | ||
+ | |||
+ | Circuit: * transistor characteristic curves | ||
+ | |||
+ | Doing analysis at TEMP = 27.000000 and TNOM = 27.000000 | ||
+ | |||
+ | |||
+ | No. of Data Rows : 251 | ||
+ | ngspice 2 -> | ||
+ | </source> | ||
+ | |||
+ | As expected, we should generate 251 points (500mV to 750mV in 1mV steps). You should also see a file named '''circuit1.dat''' in your directory. | ||
+ | |||
+ | == Viewing the Output == | ||
+ | Aside from the output file, we can view the results graphically via the ngspice interactive shell. To plot the collector current of transistor '''Q1''', type in <code>plot @Q1[ic]</code> at the prompt. | ||
+ | |||
+ | <source lang="text"> | ||
+ | ngspice 2 -> plot @Q1[ic] | ||
+ | ngspice 3 -> | ||
+ | </source> | ||
+ | |||
+ | A graph of the collector current vs. the base-emitter voltage should appear: | ||
+ | |||
+ | [[File:Circuit1 dc plot.png|thumb|center|700px|Figure 2: The collector current of transistor '''Q1''' as the base-emitter voltage is varied from 500mV to 750mV in 1mV steps.]] | ||
+ | |||
+ | As expected, the graph is exponential since, ideally, <math>I_C=I_S \cdot e^{\frac{V_{BE}}{n\cdot V_T}}</math>. | ||
+ | |||
+ | == End of the ngspice Tutorial == | ||
+ | Congratulations! You have successfully installed ngspice on your computer, and simulated the effects of varying the base-emitter voltage of an NPN BJT on its collector current. | ||
+ | |||
+ | == Notes == | ||
+ | <references group="fn"/> |
Latest revision as of 09:48, 18 February 2021
Predicting the behavior of an electronic circuit using simulation tools enables us to run experiments, explore a larger set of alternatives, and verify results quickly and inexpensively.
Most modern circuit simulators are based on the SPICE (Simulation Program with Integrated Circuit Emphasis) simulator, developed at UC Berkeley, and first presented in 1973. In this tutorial, we will use ngspice, and just like the original Berkeley SPICE, it is open source.
Contents
Classes Using this Tutorial
- CoE 197U Introduction to Analog and Digital Integrated Circuit Design
- EE 220 Analog Integrated Circuits
Installing ngspice
ngspice is available for Linux, MacOS, and Windows machines. Visit the ngspice download page for specific installation instructions. The user manual is available here.
Our First Circuit
Let's simulate the circuit in Fig. 1 using ngspice. Note that we labeled every device (Q1, Vbe, and Vce), as well as labeled every unique node (b1, c1, and 0).
First, we need to describe the circuit using a "SPICE deck". In the 1970's, punched cards were used, and hence the reference to a "deck" of cards. Now, this just refers to a text file containing a description of our circuit. Since our description will contain circuit elements and nodes (or "nets"), this file is also commonly known as a "netlist".
This is the netlist for the circuit in Figure 1:
1 * Transistor Characteristic Curves
2 * LPA 2020-04-16
3
4 .include 2N2222A.lib
5 .options savecurrents
6
7 Q1 c1 b1 0 Q2n2222a
8 Vbe b1 0 dc 0
9 Vce c1 0 dc 0.2
10
11 .control
12
13 dc Vbe 500m 750m 1m
14
15 wrdata circuit1.dat @Q1[ic]
16
17 .endc
18
19 .end
Parts of a Netlist
The first line of a SPICE netlist is treated as the circuit title or description, and is always ignored by the simulator. Comments, like the one in line 2, are preceeded by an asterisk, (*).
SPICE “dot commands” are commands that provide directives to the simulator. These are the commands in lines 4, 5, 11, 17, and 19.
- The
.include <filename>
command includes other files, such as those that contain model information. In this case,.include 2N2222A.lib
(line 4) adds the model file for a transistor, the 2N2222A NPN BJT. When you download the model file, make sure you rename it correctly[fn 1]. - The
.options savecurrents
(line 5) command tells the simulator to save the current data, since by default, only voltage data is saved. - The
.control
and.endc
encapsulate the control statements, which specify which analyses will be performed by the simulator. - The
.end
command signifies the end of the netlist file.
The main part of the netlist is the list of devices together with the nodes where the terminals of these devices are connected to.
- Line 7 instantiates a BJT with format:
Qxxx <collector node> <base node> <emitter node> <model name>
- The instance name of a BJT always starts with a Q, and is followed by the names of the nodes connected to its collector, base, and emitter. You can choose the names of the nodes. Note that, by convention, node 0 is the ground node. The model name is the name given in the model file.
- Lines 8 and 9 instantiate the voltage sources Vbe and Vce using:
Vxxx <pos> <neg> <parameters>
- In this case, Vbe and Vce are both ideal DC voltage sources with values 0.0V and 0.2V respectively.
Analysis Statements are placed inside the control block, and specify which analysis needs to be performed. Line 13 tells the simulator to perform a DC Analysis, i.e. sweep a source voltage or current and determine the behavior of the circuit. In this case, the simulator will vary Vbe from 500mV to 750mV in steps of 1mV. A DC analysis can be invoked by:
dc <independent source> <start> <stop> <step>
Line 15 instructs the simulator to write the collector current data of transistor Q1 (using the '@' directive) to a file named circuit1.dat.
Save this netlist to a directory as circuit1.sp. Go to this directory and we will run ngspice from there.
Running the Simulation
The simulator can be invoked by running ngspice
from the command line. This brings up the simulator in interactive mode, and you are presented with a prompt:
******
** ngspice-31 : Circuit level simulation program
** The U. C. Berkeley CAD Group
** Copyright 1985-1994, Regents of the University of California.
** Please get your ngspice manual from http://ngspice.sourceforge.net/docs.html
** Please file your bug-reports at http://ngspice.sourceforge.net/bugrep.html
******
ngspice 1 ->
To run the simulator, type in the command source circuit1.sp
:
ngspice 1 -> source circuit1.sp
Circuit: * transistor characteristic curves
Doing analysis at TEMP = 27.000000 and TNOM = 27.000000
No. of Data Rows : 251
ngspice 2 ->
As expected, we should generate 251 points (500mV to 750mV in 1mV steps). You should also see a file named circuit1.dat in your directory.
Viewing the Output
Aside from the output file, we can view the results graphically via the ngspice interactive shell. To plot the collector current of transistor Q1, type in plot @Q1[ic]
at the prompt.
ngspice 2 -> plot @Q1[ic]
ngspice 3 ->
A graph of the collector current vs. the base-emitter voltage should appear:
As expected, the graph is exponential since, ideally, .
End of the ngspice Tutorial
Congratulations! You have successfully installed ngspice on your computer, and simulated the effects of varying the base-emitter voltage of an NPN BJT on its collector current.
Notes
- ↑ The original model file name has a .TXT extension that, depending on your system, could be hidden.