1. EE141 Fall 2004 Discussion 1 Tips for Using SPICE

2. Discussion Operation Discussion talks about technical details that could help understanding the class material Tips in using the circuit design tools Advices on preparing for the projects and homeworks Discussing common mistakes / misunderstandings in the graded homeworks Review on some typical old exam problems Open to questions and discussions

3. Computer Accounts for Students You must have an Instructional UNIX account, using your existing account on the Instructinal systems, including c199.eecs and quasar.eecs in a few weeks. For more information, http://www-inst.eecs.berkeley.edu/ Get Your Self Ready

4. SPICE  Originated from the work of a number of talented grad. Students in EECS Dept. of UC, Berkeley, under the guidance of D. Pederson and R. Rohrer.  The universal acceptance is due not only to its robustness and ease of use but also to its original free distribution by UCB.  In nowadays research is still going on to make SPICE faster, more reliable and extending the area of its application.  The main computer-aided analysis program used in circuit design for the last 30 years

5. Where to Use HSPICE is available for instructional use on (in order of preference): c199.eecs.berkeley.edu quasar.eecs.berkeley.edu cory.eecs.berkeley.edu

6. Getting Started Musts: Input files must have the extension.sp for the waveform viewer to work. The input file must have “.OPTION POST ” specified.  Run the simulator on your input file: hspice filename.sp >! filename.lis  Use the waveform viewer to see the output: awaves Documental helps:  Resources section on EE141 website  Do not print it out! (hspice manual is 10MB, over 1900 pages)  “The SPICE Book” by Andrei Vladimirescu

7. Netlist Format The input files are case insensitive. The first line is always a comment. Other lines are commented with a leading * or $ All nonlinear devices must have a.MODEL statement. Modeling of nonlinear elements Circuit netlist Control statements Analysis

8. Names Can contain letters, numbers, and the characters ! # $ % * + - / [ ] _ Can be 1024 characters long Node names can begin with letters, numbers, or the characters # _ ! % Trailing alphabetic characters are ignored in net names. For example a node named 1A is considered to be equivalent to node 1 Nodes named 0, GND, GND!, and GROUND all refer to the global ground node.

9. Values Scientific notation: e.g. 1.1e-17 Use a suffix: e.g. 2.3u (x=mega, k=kilo, m=mili, u=micro, n=nano, p=pico, f=femto) Use a parameter: e.g. Kratio (parameters must be declared with a.PARAM statement) Evaluated expressions: e.g. ‘ 500m*Kratio ’  Voltage between two nodes: v(n1,n2)  Voltage of a node relative to ground: v(n1)  Current through an independent source: i(vin) Output Variables

10. Control.INCLUDE – includes a file, usually a model file, or a subcircuit file.OPTION – sets simulation options, e.g.OPTION POST.ALTER – but allows another simulation to be performed with the same setup except the changes that follow the.ALTER statement.END – marks the end of an input file

11. Analysis OP Operating point, DC circuit solution.DC Sweep of DC operating points (capacitances are ignored).DC var startval stopval incr - performs a DC sweep on the independent source or parameter var, varying its value from startval to stopval using the increment incr..TRAN Perform a transient analysis (differential equation solver).TRAN tincr tstop – finds the operating point (.OP) and then performs a transient analysis of duration tstop seconds with a maximum time step of tincr..AC Frequency sweep – used in analog design to find the frequency responds of a circuit

12. Measurement.MEASURE TRAN t_delay TRIG v(in) VAL=2.5 CROSS=1 TARG v(out) VAL=2.5 CROSS=1 Measures the propagation delay between the nodes in and out, where the signals first cross 2.5 volts..MEAS TRAN t_rise TRIG v(out) VAL=0.5 RISE=1 TARG v(out) VAL=4.5 RISE=1 Measures the first 10%-90% rise time of a 5V signal.MEAS TRAN max_current MAX I(Vdd) Measures the maximum current through the independent source Vdd.MEAS peak_power PARAM= ’ max_current*5 ’ Calculates the peak power, assuming that max_current has been measured

13. Trouble Shooting — Failure to Converge Non-convergence happens in OP, DC and TRAN analysis when SPICE can ’ t find solution to the circuit calculation with the input control and circuit setup  Typical error messages: – *ERROR* : NO CONVERGENCE IN DC ANALYSIS – *ERROR* : INTERNAL TIME STEP TOO SMALL IN TRANSIENT ANALYSIS  To deal with it… – In digital circuit simulation, CHECK THE CIRCUIT CONNECTIONS. – In analog circuit simulation, do hand analysis / change control options / simplify models …

14. Trouble Shooting — No DC Path to Ground (OP and DC) – This often happens with floating MOSFET gates. Just add a resistor between the node and ground, or use the.IC or.NODESET commands to create an initial condition. Be warned, however, that.NODESET and.IC can cause convergence problems.

15. Trouble Shooting — Stability Problems (TRAN) – Sometimes a transient analysis shows a “ ringing ” or oscillation that shouldn ’ t be there. This can often be solved by reducing the maximum time step or using slower rise and fall times for independent sources

16. Next — The Hand Analysis A good designer must be equipped with two weapons: –The ability to get the most help from tools –The intuition into the design System definition / integration Architecture management Circuit optimization Device modeling – Simplified models of device operation with only first- order effect suffices to help us develop intuitions into the circuit functions / performances design.