Histories
Histories provide data from each time step of a simulation. They can provide useful diagnostics to make sure your simulation is proceeding as intended. Some histories are only available with certain simulation setups (e.g. only available in electromagnetic simulation, or only available in simulations with particles).
To add a history, right-click the “Histories” element of the setup tree then navigate to the history to be added to the simulation
Field History
Field Histories record on a per time-step basis. Field histories are used to measure quantities such as the value or energy of the field at a location. The output will be a 1D array of the value vs time.
- Accelerating Voltage
This history creates a test electron and measures the accelerating voltage received by an electron traveling at a fixed velocity across a gap in a cavity structure. See acceleratingVoltage for a reference defining ‘acclerating voltage’.
- kind (not editable)
Accelerating Voltage
- description
A comment to describe the history.
- start coordinate 0
The starting position of the test electron in the x-direction in Cartesian simulations (or z-direction in cylindrical simulations).
- start coordinate 1
The starting position of the test electron in the y-direction in Cartesian simulations (or r-direction in cylindrical simulations).
- start coordinate 2
The starting position of the test electron in the z-direction in Cartesian simulations (or phi-direction in cylindrical simulations).
- end coordinate 0
The starting position of the test electron in the x-direction in Cartesian simulations (or z-direction in cylindrical simulations).
- end coordinate 1
The starting position of the test electron in the y-direction in Cartesian simulations (or r-direction in cylindrical simulations).
- end coordinate 2
The starting position of the test electron in the z-direction in Cartesian simulations (or phi-direction in cylindrical simulations).
- velocity
The velocity of the test electron. By default this is the speed of light.
- EM Field Energy
Calculate the total energy of the electromagnetic field in the specified volume (Joules). Only available in electromagnetic simulations.
- kind (not editable)
EM Field Energy
- volume
The region over which to calculate the field energy.
- simulation region
Use the entire simulation domain.
- index 3d slab
A user-defined volume based on cell indices.
- lower indices
The lower indices of the volume.
- upper indices
The upper indices of the volume.
- shape
A volume based on a previously defined geometry.
- object name
Select from a previously defined geometry.
- EM Field On Plane
ONLY AVAILABLE IN ELECTROMAGNETIC SIMULATIONS
Records E and B Field data in the plane of cells specified, typically used for computation of S Parameters using computeSParams Analyzers. The Two histories created will be historyName*_E and *historyName_B.
- kind (not editable)
S Parameter
- surface
The plane to use.
yz
- offset
The x offset from zero, in meters.
- yMin
The location of the y minimum, in meters.
- yMax
The location of the y maximum, in meters.
- zMin
The location of the z minimum, in meters.
- zMax
The location of the z maximum, in meters.
xz
- offset
The y offset from zero, in meters.
- xMin
The location of the x minimum, in meters.
- xMax
The location of the x maximum, in meters.
- zMin
The location of the z minimum, in meters.
- zMax
The location of the z maximum, in meters.
xy
- offset
The z offset from zero, in meters.
- xMin
The location of the x minimum, in meters.
- xMax
The location of the x maximum, in meters.
- yMin
The location of the y minimum, in meters.
- yMax
The location of the y maximum, in meters.
- Electric Field Energy
Calculate the total energy of the electric field in the specified volume (Joules).
- kind (not editable)
Electric Field Energy
- volume
The region over which to calculate the field energy.
- simulation region
Use the entire simulation domain.
- index 3d slab
A user-defined volume based on cell indices.
- lower indices
The lower indices of the volume.
- upper indices
The upper indices of the volume.
- Field at Position
Record the specified field at the specified coordinates. All components of the field are recorded into an array.
- kind (not editable)
Field at Position
- field
Select the desired field.
- coordinate 0
The position coordinate in the 0th dimension, x in cartesian coordinates, z in cylindrical.
- coordinate 1
The position coordinate in the 1st dimension, y in cartesian coordinates, r in cylindrical.
- coordinate 2
The position coordinate in the 2nd dimension, z in cartesian coordinates.
- representationRadius
The size of the sphere used to show the field at position history in the setup window. Does not impact the recorded history.
- Magnetic Field Energy
Calculate the total energy of the magnetic field in the specified volume (Joules).
- kind (not editable)
Magnetic Field Energy
- volume
The region over which to calculate the field energy.
- simulation region
Use the entire simulation domain.
- index 3d slab
A user-defined volume based on cell indices.
- lower indices
The lower indices of the volume.
- upper indices
The upper indices of the volume.
- Poynting Flux
ONLY AVAILABLE IN ELECTROMAGNETIC SIMULATIONS
Calculates the integrated Poynting vector (energy flux) through the area defined by the min and max values.
- kind (not editable)
Poynting Vector
- surface
The plane to use.
yz
- offset
The x offset from zero, in meters.
- yMin
The location of the y minimum, in meters.
- yMax
The location of the y maximum, in meters.
- zMin
The location of the z minimum, in meters.
- zMax
The location of the z maximum, in meters.
xz
- offset
The y offset from zero, in meters.
- xMin
The location of the x minimum, in meters.
- xMax
The location of the x maximum, in meters.
- zMin
The location of the z minimum, in meters.
- zMax
The location of the z maximum, in meters.
xy
- offset
The z offset from zero, in meters.
- xMin
The location of the x minimum, in meters.
- xMax
The location of the x maximum, in meters.
- yMin
The location of the y minimum, in meters.
- yMax
The location of the y maximum, in meters.
- Pseudo-potential
This option is deprecated. Use ‘Pseudo-potential at Coordinates’ or ‘pseudo-potential at Indices’ instead.
- kind (not editable)
Pseudo-potential
- start indices
The indices of the cells for the starting location.
- end indices
The indices of the cells for the ending location.
- Pseudo-potential at Coordinates
Calculates the pseudo-potential difference, in Volts, between two points. The start point would correspond to the measure point, while the end point would correspond to the reference.
- kind (not editable)
Pseudo-potential
- start coordinate 0
The coordinate of the start point in the 0th dimension.
- start coordinate 1
The coordinate of the start point in the 1st dimension.
- start coordinate 2
The coordinate of the start point in the 2nd dimension.
- end coordinate 0
The coordinate of the end point in the 0th dimension.
- end coordinate 1
The coordinate of the end point in the 1st dimension.
- end coordinate 2
The coordinate of the end point in the 2nd dimension.
- Pseudo-potential at Indices
Calculates the pseudo-potential difference, in Volts, between two points, specified by grid index.
- kind (not editable)
Pseudo-potential
- description
A description of the potential difference.
- start indices
The indices of the cells for the starting location.
- end indices
The indices of the cells for the ending location.
Particle History
Particle Histories record on a per time-step basis. Particle histories are used to measure quantities such as the total number of particles in a simulation at each step, or the current absorbed at chosen absorbing surface at each step. The output will be a 1D array of the value vs time.
- Absorbed Particle Current
Calculates the absorbed current on a specified particle absorber, in Amps.
- kind (not editable)
Absorbed Particle Current
- particle absorber
Select the previously defined particle absorbing boundary condition. This must be a ParticleBoundaryCondition that can Save.
- Absorbed Particle Power
Calculates the power absorbed on a specified particle absorber, in Joules/second.
- kind (not editable)
Absorbed Particle Power
- particle absorber
Select the previously defined particle absorbing boundary condition. This must be a ParticleBoundaryCondition that can Save particle data.
- Emitted Current
Records the emitted current from the specified particle emitter, in Amps. If trying to track the current from a secondary emitter it is necessary to use the Log History Emitted Particle Log
- kind (not editable)
Emitted Current
- particle emitter
Select the previously defined particle emitting boundary condition.
- Number of Macroparticles
Calculates the total number of macroparticles in the simulation domain for the specified KineticParticle.
- kind (not editable)
Number of Macroparticles
- particles
Select the name of the previously defined KineticParticles.
- Number of Physical Particles
Calculates the total number of real particles in the simulation domain for the specified KineticParticle.
- kind (not editable)
Number of Physical Particles
- particles
Select the name of the previously defined KineticParticles.
- Particle Energy
Calculates the total energy in the simulation domain for the specified KineticParticle, in Joules.
- kind (not editable)
Particle Energy
- particles
Select the name of the previously defined KineticParticles.
- Particle Energy Change from Boundary
Calculates the energy change in a particle species due to a diffuse reflector boundary condition.
- kind (not editable)
Particle Energy Change from Boundary
- particle absorber
Select the name of the boundary diffuse reflector particle boundary condition.
Combo History
Combo Histories are used to create new histories by combining other histories. The operation is done at every time step and the resulting output will be a 1D array of the value vs time. Any number of histories may be combined.
Note
Due to the nature of the combination process, a combo history will always use data from the previous timestep as compared to the other histories, and will be initialized with a value of 1. The Combined history will not have data from the last timestep of the simulation.
- kind (not editable)
Combination History
- Constituent History
As many constituent histories as desired may be added. The name of the constituent history itself is not of particular importance.
- history name
Select one previously defined Field or Particle History.
- coefficient
This is a multiplying factor on the selected history.
- combination
This operation will be applied to combine the history with all preceding constituent histories. The order of operations is demonstrated in an example with three histories of each below
- add
(coefficient1*history name 1) + (coefficient2*history name 2) + (coefficient3*history name 3)
- subtract
(coefficient1*his:command:Accelerating Voltage
This history creates a test electron and measures the accelerating voltage received by an electron traveling at a fixed velocity across a gap in a cavity structure. See acceleratingVoltage for a reference defining ‘acclerating voltage’.
- kind (not editable)
Accelerating Voltage
- description
A comment to describe the history.
- start coordinate 0
The starting position of the test electron in the x-direction in Cartesian simulations (or z-direction in cylindrical simulations).
- start coordinate 1
The starting position of the test electron in the y-direction in Cartesian simulations (or r-direction in cylindrical simulations).
- start coordinate 2
The starting position of the test electron in the z-direction in Cartesian simulations (or phi-direction in cylindrical simulations).
- end coordinate 0
The starting position of the test electron in the x-direction in Cartesian simulations (or z-direction in cylindrical simulations).
- end coordinate 1
The starting position of the test electron in the y-direction in Cartesian simulations (or r-direction in cylindrical simulations).
- end coordinate 2
The starting position of the test electron in the z-direction in Cartesian simulations (or phi-direction in cylindrical simulations).
- velocity
The velocity of the test electron. By default this is the speed of light.
- tory name 1) - (coefficient2*history name 2) - (coefficient3*history name 3)
- multiply
(( (coefficient1*history name 1)) * (coefficient2*history name 2)) * (coefficient3*history name 3)
- divide
(( (coefficient1*history name 1)) / (coefficient2*history name 2)) / (coefficient3*history name 3)
As the above examples show, using a multiply or divide operation on the third or greater constituent history, will multiply or divide by the combination of all preceding histories.
- Time Average
This history can reference other particle and field histories, averaging them in the selected time window.
- kind (not editable)
Time Average
- history name
The history to be averaged.
- time window
The time window to be doing the averaging in.
Array History
An Array History will output an array of data for each time-step.
- Far-Field Box Data
ONLY AVAILABLE IN ELECTROMAGNETIC SIMULATIONS
- kind (not editable)
Far-Field Box Data
- measurement time
The way to define measurement time.
seconds defined Gives specification of time in seconds.
- start time
The time to start recording data for far field calculations (seconds).
- end time
The time to stop recording data for far field calculations (seconds).
timesteps defined Gives specification of time in timestep number.
- start time
The time to start recording data for far field calculations (timesteps).
- end time
The time to stop recording data for far field calculations (timesteps).
- volume
The volume to use for the box.
cartesian 3d slab
- xMin
The minimum x position of the box.
- xMax
The maximum x position of the box.
- yMin
The minimum y position of the box.
- yMax
The maximum y position of the box.
- zMin
The minimum z position of the box.
- zMax
The maximum z position of the box.
index 3d slab Index 3d slab is used in cases where absolute symmetry is necessary so grid alignment must be guranteed.
- lower index 0
The lower grid cell of the box in the 0th direction.
- lower index 1
The lower grid cell of the box in the 1st direction.
- lower index 2
The lower grid cell of the box in the 2nd direction.
- upper index 0
The upper grid cell of the box in the 0th direction.
- upper index 1
The upper grid cell of the box in the 1st direction.
- upper index 2
The upper grid cell of the box in the 2nd direction.
- Field Slab Data
Store the value of a field at every timestep within a specified 3D volume.
- kind (not editable)
Field Slab Data
- description
A comment to describe the history.
- field
Choose the field to record. Options for electromagnetic simulations are:
Electric Field
Magnetic Field
Options for electromagnetic simulations are:
Phi
Charge Density
Electric Field
- volume
The volume inside of which to collect the field data.
cartesian 3d slab
- xMin
The minimum x position of the box.
- xMax
The maximum x position of the box.
- yMin
The minimum y position of the box.
- yMax
The maximum y position of the box.
- zMin
The minimum z position of the box.
- zMax
The maximum z position of the box.
- Particle Momentum
Calculate the total momentum for a particular set of particles in the whole simulation domain. All three components of the momentum are recorded. Thus, for some simulations in 1D or 2D, some components of the momentum may always be zero.
- kind (not editable)
Particle Momentum
- particles
Select any of the previously defined KineticParticles in your simulation.
Log History
A Log History will record data based on user specified logging method. A single log history may contain multiple particle quantities.
- Absorbed Particle Log
Record information about each and every particle that strikes a chosen absorbing surface. The output will be a 1D array of the value.
- kind (not editable)
Absorbed Particle Log
- particle absorber
Select the previously defined particle absorbing boundary condition. This must be a ParticleBoundaryCondition that can Save.
- particle quantity
What information about the particle is to be recorded. For vector-like quantities (position, velocity, and weight), you must select which component of the vector you wish to record in the component option (0 –> x, 1 –> y, 2 –> z) in Cartesian, (0 –> r, 1 –> z, 2 –> phi) in Cylindrical.
- particle time
The time the particle strikes the absorber.
- particle position
The position of the particle when it is absorbed.
- particle velocity
The velocity of the particle when it is absorbed (Non-relativistic m/s).
- particle weight
The weight of the particle when it is absorbed.
- particle energy
The total relativistic energy of all the particles that are absorbed (Joules).
- particle current
The total current of all the particles that are absorbed (Amps, the charge divided by timestep).
- particle gamma velocity
The gamma velocity of the particle when it is absorbed (relativistic m/s).
- particle charge
The charge of the particle when it is absorbed (Coulombs).
- particles in macro particle
The number of particles in that macro particle when it is absorbed.
- particle mass
The total mass of the macro particle (kilograms).
- Emitted Particle Log
Record information about each and every particle that is emitted from a particle emitter. The output will be a 1D array of the value.
- kind (not editable)
Emitted Particle Log
- particle emitter
Select the previously defined particle emitter. Any emitter type is applicable.
- particle quantity
What information about the particle is to be recorded. For vector-like quantities (position, velocity, and weight), you must select which component of the vector you wish to record in the component option (0 –> x, 1 –> y, 2 –> z) in Cartesian, (0 –> r, 1 –> z, 2 –> phi) in Cylindrical.
- particle time
The time the particle is emitted
- particle position
The position of the particle when it is emitted.
- particle velocity
The velocity of the particle when it is emitted (Non-relativistic m/s).
- particle weight
The weight of the particle when it is emitted.
- particle energy
The total relativistic energy of all the particles that are emitted (Joules).
- particle current
The total current of all the particles that are emitted (Amps, the charge divided by timestep).
- particle gamma velocity
The gamma velocity of the particle when it is emitted (relativistic m/s).
- particle charge
The charge of the particle when it is emitted (Coulombs).
- particles in macro particle
The number of particles in that macro particle when it is emitted.
- particle mass
The total mass of the macro particle (kilograms).