Convergence

Simulations sometimes fail to converge - that is the simulation aborts before completion with one of these messages:

  • No convergence in transient analysis
  • No convergence in DC analysis
  • Cannot find DC operating point - Iteration limit exceeded in pseudo transient analysis
  • Cannot find DC operating point - No convergence in pseudo transient analysis

Convergence failures can be fixed by setting appropriate simulation options or by making changes to the circuit or by making changes to the models. Sometimes a combination of all three is required. See the following sections for more information:

In this topic:

Convergence Options

Select menu Simulator > Convergence Options. You will be presented with this dialog box:

This dialog allows to set a number of simulation options that can help simulation convergence. These options sometimes have a penalty, either they slow down the simulation or in some way degrade accuracy. These are described below

Item Description
Iteration mode Selects solver iteration and mode. Each of these options improves convergence at the expense of simulation speed. Extended precision mode provides a worthwhile convergence improvement with only a modest speed loss.
Tolerances Setting current tolerance to 1n sometimes fixes convergence problems. You should not increase this setting if your circuit has very small currents
Time step The Minimum Time step has a default value of 1e-18s. Lower values sometimes help transient analysis especially if using quad precision iteration modes. Increasing this value does not improve simulation speed. This value sets the lower limit below which the simulation will abort
Slew rate for discontinuous sources This will only have an effect if you use models that contain discontinuous sources. These are common in switching power controllers
Shunt capacitance This is often effective especially if the Apply shunt capacitance globally box is checked. However, this option is effectively modifying your circuit so should always be used with care. Note that this option will only benefit transient analysis

Iteration Mode

The iteration mode trades off simulation speed with numerical noise. Numerical noise is one of the major causes of simulation failure in transient analysis. Numerical noise is the noise induced as a result of uncertainly in a calculation due to the limited precision of the arithmetic and is sometimes referred to as round-off error. It is similar in concept to quantization noise that is prevalent in data converters. Numerical noise increases as the time step reduces due to the behaviour of reactive components and can reach levels that exceed the tolerance parameters that determine when convergence has been reached.

SIMetrix provides a range of iteration modes that reduce numerical noise by employing a higher precision in its numerical calculations. In addition SIMetrix offers an advanced iteration mode which lowers numerical noise by employing a more efficient iterative equation.

Mode Typical numerical Typical simulation Advanced Precision
Fast mode 10 x see notes Yes Double
Normal 1 x 1x No Double/Extended
Advanced

iteration
???MATH???\div???MATH??? 100 + 5% Yes Double/Extended
Extended

precision
???MATH???\div???MATH??? 10000 + 10%-30% Yes Extended
Extended/quad

precision
???MATH???\div???MATH??? 1e18 2x to 8x Yes Extended/Quad
Quad

precision
???MATH???\div???MATH??? 1e18 4x to 10x Yes Quad

Double precision has a decimal resolution of approximately 16 digits. Extended precision has a decimal resolution of approximately 19 digits. Quad precision has a decimal resolution of approximately 34 digits

Fast mode can be useful for circuits that contain large passive networks as is commonly obtained from parasitic extraction tools. While not offering any convergence benefit, this mode can run significantly faster for such circuits.

Convergence Failure Report

The convergence failure report provides details of items that caused the convergence failure. To create a convergence report, select menu Simulator > Convergence Report. The report is divided into the following sections:

Nodes which failed

to converge on the final step
Lists circuit nodes whose failure to converge led to the simulation aborting. These should usually be the initial focus for investigation. These nodes will be highlighted on the schematic if at the top level of the hierarchy and this often shows the general area that is giving trouble
Devices which failed

to converge on the final step
Devices whose failure to converge led to the simulation aborting
Items which failed

to converge earlier in the run
The items listed here did not necessarily lead to the failure. However, devices or nodes that often fail during a run may be worth investigating. The Count value indicates how often the item failed.
Nodes which overflowed

during the run
If a node voltage exceeds a preset limit, the iteration is aborted and then repeated with a smaller step. This is not necessarily a cause for concern but if the same node frequently overflows, this could be indicative of some problem
Static audit of circuit Result of a static analysis of the circuit. See below for further details

Convergence Static Analysis

The convergence static analysis feature performs an analysis of the circuit to identify items that can give trouble and could lead to convergence failure. The static analysis is automatically performed as part of the convergence failure report but may also be run on its own before or after a simulation using the menu Simulator > Convergence Static Audit. If run before a simulation, a dummy run of the simulation will be required and you will be prompted whether you would like this to be performed. This will load the circuit into the simulator but not actually start the run.

The static analysis will identify the following potential problems:

Code Description
IfDiscontinuity Arbitrary source expression in the form IF(expression, constant, constant). These are discontinuous as they switch abruptly from one value to another with no time definition. This can lead to convergence failure
SgnDiscontinuity Use of Sgn (sign) function in an arbitrary source. These can be discontinuous although it depends on how they are used. If this is reported in an Infineon MOSFET or IGBT model then it can be safely ignored
StpDiscontinuity Use of U() or Stp() functions in an arbitrary source. Can be discontinuous but depends on how they are used
FloorDiscontinuity Use of floor function in an arbitrary source. This is discontinuous and often gives convergence problems
DivideByZero A divide by zero condition was detected in an arbitrary source
DivideByVar This means something of the form expression/V(n1) or expression/(V(n1,n2) or expression/(V(n1)-V(n2)) or expression/I(v). In each case the V() or I() access function can - and usually does - return zero at some point leading to a divide-by-zero error
ValueTooSmall A model or device parameter was set to a value that is too small. An example is the N parameter for a diode model. Small values are often used in models in order to make a diode with a small voltage drop but this can lead to difficulty in some situations.
ValueTooLarge A model or device parameter was set to a value that is too small. Large capacitors trigger this failure for example