10000 - 13999 information messages

ID Message text and information
10001 <number>
10101 Free face element generation summary

On Face <integer> of element<ID> element <ID> was generated
10102 Nonhomogeneous multilayer element generation summary. The list includes the elements generated behind the top element in the order they are generated including the reverse sides Element ID List of elements generated behind it
10103 <List of integers>
10104 Details of coincident node merging Old node ID New node ID. (<ID>)
10105 Multispectral Data Summary. Number of spectral bands: <number> Constant in Planck''s spectral energy distribution <value> <value> IR and solar spectrum separation is at <value> microns Band limits in microns:. (Band <integer> <value>--> <value>)
10106 Free Molecular Heating Orbital Data. Time Velocity Veloc. Veloc. Altitude Density Flux THETA PHI
10107 <value>
10108 Protective Layers element generation summary. The list includes the elements generated above the original element in the order they are generated Element ID List of elements generated on top of it
10109 <integer> <integer>

<list of integers>
10110 Stream A is farther to a junction than the length of the shortest stream of the junction (stream A):
10111 - Junction: A
10112 List of Duct Inlet/Outlet BCs:
10113 - Duct Inlet/Outlet: A
10114 List of invalid Fan/pump BC Elements:
10115 - Element: <ID>
10116 List of invalid Duct opening BC Elements:
10117 Group <name> contains <integer> element(s):
10118 <List of integers>
10301 Edge Interface Resistance.

Original Node Duplicated Nodes
10302 <List of integers>
10303 Edge Interface Resistance.

Original Element Duplicated Elements
10304 <List of integers>
10401 Circular element <ID> <name> was subdivided into elements <list of IDs>
10402 Nearest to <ID> <name> is <ID> <name> - <name> overlap=<value>
10403 Element =<ID> <value> and Earth do not face each other at time =<value>
10404 Element =<ID> EarthVF =<value> at time =<value> Sub. Param =<ID>

Element =<ID> Albedo Factor =<value> at time =<value> Sub. Param =<ID><value>

Planet block factor =<value> Albedo block factor =<value>
10405 Planet: Theta=<value> Phi=<value> Sun: Theta=<value> Phi=<value> Albedo=<value> H/R=<value>
10406 No shadowing elements
10407 No shadowing surfaces
10408 Shadowing elements used in calculations <list of IDs>
10409 Shadowing surfaces used in calculations <list of IDs>
10410 Possibly shadowing elements not used in calculations <list of IDs>
10411 Possibly shadowing surfaces not used in calculations <list of IDs>
10412 Element <ID> was merged with element<ID>
10413 Element =<ID> SunVF=<value> does not face the sun
10414 Sun: Theta=<value> Phi=<value> Time=<value>
10415 I=<integer> J=<integer> do not face each other
10416 I=<integer> J=<integer> estimated view factor. Minimum=<value> - not computed
10417 Shadowing surfaces report.

Number of shadowing surfaces =<integer> created from <integer> elements
10418 Shadowing surface <ID> contains only element<ID>
10419 Shadowing surface <ID>
10420 The surface has at least one hole in it
10421 Surface CG (X, Y,Z) <value> <value> <value>
10422 Surface normal (I,J,K) <value> <value> <value>
10423 Surface area <value> <value> <value>
10424 Min and max radii from CG <value> <value>
10425 Number of elements in surface <ID>
10426 List of elements <list of element IDs>
10427 List of perimeter nodes <list of perimeter node IDs>
10428 Solar ray trace<ID> at time=<value>
10429 Heat flux view factor ray trace<ID> at time=<value>
10430 Specular view factor trace<ID> for element<ID>
10431 Solstr=<value> IRstr=<value> X=<value> Y=<value> Z=<value>
10432 Sun Solstr=<value> IRstr=<value> X=<value> Y=<value> Z=<value>
10433 Space Solstr=<value> IRstr=<value>
10434 <integer> <integer> <value> <value> <value>
10435 Two spheres intersect, view factor may be incorrect
10436 I=<ID> Sun SunVF=<value> at time =<value> Earth blockage
10437 View Factor module calculation results.
10438 I=<integer> J=<integer> VFij=<value> VFji=<value> Ai*VFij=<value> Subdiv=<ID>
10439 I=<integer> J= Sun SunVF=<value> Ai*SunVF=<value> Subdiv=<ID>
10440 Time=<value>
10441 Specular reflection of ray off element <ID> originating from the Sun
10442 Specular reflection of ray off element<ID> originating from <ID>
10443 Shadowing volume report.

Parameters for generating shadowing volumes:

Number of elements in shadowing surface to identify small surface =<integer>

Total number of shadowing surfaces which triggers shadowing

volume generation =<integer>

Minimum number of shadowing surfaces per shadowing volume =<integer>

Number of shadowing volumes created = <integer>
10444 Shadowing volume <ID> Volume minimum (X,Y,Z) <value> <value> <value>
10445 Volume maximum (X,Y,Z) <value> <value> <value>
10446 List of shadowing surfaces completely in volume <list of IDs>
10447 List of shadowing surfaces partially in volume <list of IDs>
10448 Angle dependent properties associated with BRDF in array <integer>

Inc Angle(deg)Emiss.BRDF-RefSpec-Ref Trans. Diff-Trans
10449 <value> <value> <value> <value> <value> <value>
10450 Total effective emissivity=<value>
10501 Results after view factor adjustment.

Maximum view factor sum =<value> at element <ID> <name>

Minimum view factor sum =<value> at element <ID> <name>

Unadjusted black body view factor sums sorted according to deviation from unity
10502 Element no.<ID> Sum =<value> Deviation =<value> <name>
10503 Oppenheim element <ID> created for element <ID>
10504 View factor printout summary for selected elements. Element i Element j Unadjusted Vfij Adjusted Vfij
10505 <integer> <integer> <value> <value>
10506 View factor sum <value> <value>
10507 View factors for element <ID>
10508 Element <ID> Oppenheim element: <string>
10509 For element<ID> Oppenheim element is: none, reverse side is:<integer>
10510 For element <ID> Oppenheim element is: <ID>, reverse side is: none
10511 Multispectral run for band<ID> lambda range:<value>-><value> microns
10512 The Oppenheim element(s) for the <ID> IR spectrum bands used in radiative exchange calculations are: Element Oppenheim elements
10513 <List of integers>
10514 Oppenheim method used, new elements created with an increment of <integer>
10515 The residual view factors are to the elements themselves.
10516 KSP =<integer> The residual view factors are to element <ID>
10517 Calculation data for the <name> Module
10518 No radiative couplings created.
10519 View factor adjustment is performed...
10520 Enclosure no.<ID> contains <integer> elements
11101 Element <ID> <name> was merged into element<ID> <name>
11102 Element renumbering and radiation patching statistics for the MEREL Module
11103 Element generation for homogeneous multilayer elements (bottom to top)
11104 Element <ID> was split into layers <list of IDs>
11105 Table <ID> was created from table <ID> in the INPF file.
11106 Array <ID> was created from array <ID> in the INPF file.
11107 Oppenheim element <ID> from this articulation time step relabeled to <ID>
11108 Cond. vs. time table <ID> created for conductance number <ID>
11109 <value> <value>
11110 Results of radiation patching
11111 Patch no<ID> contains <ID> elements: <List of IDs>
11112 Results of wavelength-dependent emissivity calculations
11113 Element: <ID> Band Wavelength Range Emissivity Oppenheim Element
11114 <number> <value>-> <value> <value> <number>
11115 Elements With 0 Convection
11116 <List of integers>
11117 Boundary Conditions With 0 Convection
11118

List of Elements With 0 Convection for this BC:
11119 Elements With High Thickness
11201 Summary for hydraulic elements
11202 Ambient pressure (absolute) =<value>

Ambient density =<value>

Ambient temperature =<value>

Average density =<value>
11203 Average viscosity =<value>

Maximum Reynolds number =<value> at element <ID> <name>

Minimum Reynolds number =<value> at element <ID> <name>

Average Reynolds number =<value>
11204 Maximum static pressure =<value> at element<ID> <name>

Minimum static pressure =<value> at element <ID> <name>

Maximum dynamic pressure =<value> at element <ID> <name>
11205 Minimum dynamic pressure =<value> at element<ID> <name>
11206 Maximum heat balance deviation occurs at element <ID> <name>
11208 Heat flows into element <ID> Belongs to group: Labeli Labelj Cond no Boundel T(i) T(j) Cond val Htflowji Type
11209 <number> <value> <value> <type>
11210 Labeli Labelj Res no Pt(i) Pt(j) Res i-j Massflji Type
11211 <number><number> <value><value> <value> <value> <name>
11212 <number> <number> <value> <value> <value> <name>
11213 <number> H=<value> AREA(I)=<value>
11214 <number> <value> Heatload
11215 <number> <value> Flowi
11216 <ID> <value> <value> <value> Heatsum
11217 <ID> <value> <value> Massum
11218 Flow parameters summary for <ID> element

<ID> <ID> <value> Re(Dhyd) =<value> Rho =<value> Velocity =<value> <ID>

Hyd. diam=<value> Viscosity=<value> Area =<value> <value> <ID> Mass flow=<value> Vol. Flow=<value> Height =<value>

<ID> Pstatic =<value> Pdynamic =<value> Ptotal =<value> <ID> BL length=<value> Rho-Rhoam=<value> Mach No. =<value>
11219 <integer> <value> Length =<value> Ktherm =<value>

FlowInlet= <string> <integer> Kloss Eq.=<value> 4*F*R*L/D=<value> Spec. ht =<value> <ID>

dPstatic =<value> dPdynamic=<value> dPbuoyanc=<value>

<value> <integer> dPt-dPb =<value> dPtotal =<value> K*Ktable =<value>

<integer> Startelem=<ID> End elem =<integer> Nu devel.=<value>

<integer> H develop=<value> A(start) =<value> A(end) =<value>

<value> <integer> Del hght =<value> Restot =<value> Flow Dir.= <name>

<integer> F Fanning=<value> MassFloPB=<value> MachStart=<value>

<integer> MachEnd =<value> TotalTemp=<value> SoundVel =<value>
11220 Cond no Element A Element B T(A), T(B) Cond value Heat flow TYPE (P(A)) (P(B)) (FLUID FLOW)
11223 Conductance values at time =<value> 3( Number Value )
11224 Temperature values

Elem NameTempElem NameTempElem NameTemp
11225 Capacitance values

Elem NameCapElem NameCapElem NameCap
11226 Heat loads

Elem NameQElem NameQElem NameQ
11227 Total pressure values

Elem NamePressElem NamePressElem NamePress
11228 Phase change temperature values

Elem NameTempElem NameTempElem NameTemp
11229 Latent heat values

Elem NameQElem NameQElem NameQ
11230 Capacitance values below phase change temperature

Elem NameCapElem NameCapElem NameCap
11231 Capacitance values above phase change temperature

Elem NameCapElem NameCapElem NameCap
11232 Total pressure values

Elem NamePressElem NamePressElem NamePress
11233 Impressed nodal fluid flow values

Elem NameFlowElem NameFlowElem NameFlow
11234 Quality values

Elem NameQualElem NameQualElem NameQual
11235 Mass flow through elements

Elem NameMassFlElem NameMassFlElem NameMassFl
11236 <number> <value>
11237 <number> <string> <value>
11238 <number> <string> <value>
11239 <number> <string> <value>
11240 <number> <string> <value>
11241 The following describe the pressure network of the hydraulic elements
11242 Element <ID> Gsum=<value> Cap=<value> RC=<value> <name> <type>
11243 RCmin =<value> at element<ID>

RCmean =<value>

RCmax =<value> at element<ID>

Total capacitance =<value>
11244 Good approximation for radiation linearization temp. =<value>
11245 Element elimination process independent of radiation linearization temperature.
11246 Minimum temperature =<value> at element <ID> <name>

Maximum temperature =<value> at element<ID> <name>

Average temperature =<value>
11247 Boundary layer of fluid element <ID> <name> starts at element <ID> <name>
11248 Properties of fluid element <ID> <name> obtained From upstream element <ID> <name>
11249 Area of fluid element <ID> <name> obtained From upstream element <ID> <name>
11251 Summary for thermal elements
11252 Analyzer module calculation results
11253 Starting run no <number>
11254 Element Temp Qcond Qrad Qsto Qsp Qnode Qsum
11255 <integer><value><value> <value> <value> <value> <value> <value> <value>
11256 Total <value><value> <value> <value> <value> <value> <value>
11257 Total heat content (Sum C(i)*T(i)) =<value>
11258 Card 2A KSP is not an element, hence QSP=0
11259 Time=<value> Intstep=<value> RCmin=<value> at element <ID> <name>

Minimum temperature =<value> at element<ID> <name>

Maximum temperature =<value> at element<ID> <name>

Average temperature =<value>
11260 No. of iterations <integer> TDmax =<value> at element<ID>

Minimum temperature =<value> at element<ID> <name>

Maximum temperature =<value> at element<ID> <name>

Average temperature =<value>
11261 <integer><integer><integer> <value><value><value> <string>
11262 <integer><integer> <value> <value> <value> <value> <value> <string> <name>
11263 TotalTemp=<value> SoundVel =<value> Spec. ht =<value>
11264 <integer> <string> Boundary elements <List of integers>
11265 Electrical resistance power dissipation summary
11266 Labeli Labelj ViVjCondijCurrentPowerDiss
11267 <value><integer><value>
11268 At time <value> total electrical power dissipation =<value>
11269 At iteration <integer> total electrical power dissipation =<value>
11270 Total current flowing into element <ID> =<value>
11271 Total current flowing into <string> =<value>
11272 CG element <integer> has boundary elements <List of integers>
11273 <integer> <value> -C*dT/dt
11274 <integer> <integer> <value> <value> <value> <string>
11275 Group-to-Group Heat Flow Report:

TempQCapDescription

Groupi: <value> <value> <value>

Groupj:<value> <value> <value>

Type Cond. value Heat Flow <type> ScriptFij Black Body Vfij
11276 <value> <value>
11277 <value> <string>
11278 The following elements' conductances were modified to make the solution more robust. If possible, modify these elements so they are less distorted. <List of IDs>
11279 Conductive conductance matrix of element<ID> Labeli Labelj Cond no T(i) T(j) Cond val Htflowji Type
11280 <integer> <integer> Equiv* <integer> <value> <value> <value> <name>
11281 Power dissipation in element<ID>

Labeli Labelj Vi Vj Condij Current PowerDiss
11282 <value> <integer> <integer> <value> <value> <value> <value> <value>
11283 Total power dissipation in element <ID> is <value>
11284 Thermostat summary
11285 Thermostat number <integer>

Sensor element <integer> <name>

Number of heater elements <integer>

Number of times turned ON <integer>

Cut-in temperature <value>

Cut-out temperature <value>

Total time heaters are ON <value>

Duty cycle <value>%

Avg. power of heaters when ON <value>

Heater element list <list of integers>
11286 Heat flows into element <ID>Connected to fluid element <ID>

Belongs to group: <string>

Labeli Labelj Cond no Boundel T(i)T(j) Cond valHtflowjiType
11287 Temperature summary for groups

Maximum at Minimum atAverageTotal (Total) (Total)Temp element Temp element Temp Heat in CapacitanceMass
11288 Group: <value> <integer> <value> <integer> <value> <value> <value>
11289 Note: Orientation of hydraulic element <ID> was reversed internally. The reversed orientation is shown above.
11290 Approx. ScriptFij=<value> <value> <value> <value> <string>
11291 Conductance Values at time=<value> Type Labeli Labelj Value Cond Conductance No Parameter
11292 <name> <integer> <value> <integer> <value>
11293 Peltier cooler <integer> summary:

Geometrical factor: <value>

Seebeck constant: <value>

Current: <value>

Electrical Resistivity: <value>

Voltage: <value>

Number of thermocouples: <integer>

Hot group: <name>

Cold group: <name>

Thot: <value>

Tcold: <value>

Qhot after leakage: <value>

Epower: <value>

Qcold after leakage: <value>

Thermal conductivity: <value>
11294 Group-to-Group Heat Flow Report: Temp Description Groupi: <value> Groupj: <value> Type Cond.valueHeat Flow i->j
11295 Heat flow into sinks =<value>

Heat flow from non-fluid sinks =<value>

Heat load into elements =<value>

Heat load into sinks =<value>

Heat flow from fluid sinks =<value>

Deviation from heat balance =<value>
11296 Group-to-Group Heat Flow Report At Time: <value>

Temp Q Cap Description Groupi: <value> <value> <value>

Groupj: <value> <value> <value>

TypeCond.valueHeat Flow <type> Scriptfij Black Body Vfij
11297 Black Body VFij=<value>
11298 Elements created by TMG TMG element <ID> <name>
11299 Association of boundary elements and CG elements
11300 Heat Flow Summary Into Different Sink Entities: Sink Entity Temperature Heat in Heat absorbed since start
11301 <string> <value> <value>
11302 The following elements have Reynolds Numbers either below <value> or above <value> <List of integers>
11303 Peltier cooler <integer> summary:

Geometrical factor: <value>

Seebeck constant: <value>

Current: <value>

Electrical Resistivity: <value>

Voltage: <value>

Thermal conductivity:<value>

Number of thermocouples: <number>

Hot plate group: <name>

Cold plate group: <name>

Thot: <value>

Tcold: <value>

Peltier effect at Thot: <value>

Peltier effect at Tcold: <value>

Ohmic losses: <value>

Hot to cold conduction heat flow: <value>

Energy Balance: Qhot (The net heat flow to the environment) =(PeltierHot + 1/2 Ohmic - Hot2Cold Cond.Flow): <value>

Qcold (The net heat sucked at the cold plate) =(PeltierCold + 1/2 Ohmic + Hot2Cold Cond.Flow): <value>
11304 Thermostat number <integer> <string>

Sensor element <ID> <name>

Number of heater elements <integer>

Number of times turned ON <integer>

Cut-in temperature<value>

Cut-out temperature <value>

Total time heaters are ON <value>

Duty cycle <value> %

Avg. power of heaters when ON <value>

Heater element list <List of integers>
11305 Thermostat <ID> <name> is <name>
11306 Note * : An Equiv conductance is not part of the solution matrix it represents an equivalent conductive conductance between two adjacent elements. It is calculated by dividing the conductive heat flow between the two elements through their common boundary element by the temperature difference of their CG's. The element's conductance matrix is shown below.
11307 Time=<value>, Integration timestep=<value>

Cpu time in ANALYZER module=<value>

Minimum temperature =<value> at element <ID> <name>

Maximum temperature =<value> at element <ID> <name>

Average temperature =<value>
11308 Heat flow into sinks =<value>

Heat flow from non-fluid sinks =<value>

Heat load into elements =<value>

Heat load into sinks =<value>

Heat flow from fluid sinks =<value>

Deviation from heat balance =<value>
11309 <integer> <value> Multispectr
11310 Group-to-Group Heat Flow Report:

Temp QCap Description

Groupi: <value> <value> <value>

Groupj:<value> <value> <value>

Type Cond value Heat Flow <type> ScriptFij
11311 Group-to-Group Heat Flow Report At Time: <value>

Temp QCapDescription

Groupi: <value> <value> <value>

Groupj: <value> <value> <value>

Type Cond. value Heat Flow <type> ScriptFij
11312 <integer> <value> Radsolve
11313 Thermostat number <integer> <name>

Sensor element <ID><name>

Number of heater elements <integer>

Number of times turned ON (last period)<integer>

Cut-in temperature <value>

Cut-out temperature <value>

Total time heaters are ON (last period) <value>

Duty cycle (last period) <value>%

Avg. power of heaters when ON (last period) <value>

Heater element list

<List of integers>
11314 Heat flows into immersed element <ID> Belongs to group: <string>

Labeli Labelj Cond no Boundel T(i) T(j) Cond val Htflowji Type
11315 Convecting areas of Convecting Zone BCs (ID area name):
11316 Convecting areas of Thermal Void Region BCs (ID area name):
11317 Convecting areas of Thermal Stream BCs (ID area name):
11318 <integer> <value> <string>
11319 Last period is from time=<value> to time=<value>
11320 Hydraulic Subnetwork: <integer> No. Element ID -----------------------------
11321 [<integer>] <integer>
11322 Hydraulic Branching Junctions No. 0D Element ID Node ID ---------------------------------- [<integer>] <integer> <integer>
11323 ------------------------------------------------------- Thermal Correlation Sensors ----------------------------------- Sensor Name Temperature Difference Temperature
11324 ----------------------------------- -------------------------------------------------------
11325 <name> <value> <value>
11326 ------------------------------------------------------- Thermal Correlation Sensors at Time <value> ----------------------------------- Sensor Name Temperature Difference Temperature
11601 Orbital position calculations
11602 Vehicle orbit coordinate system is planet oriented
11603 Vehicle orbit coordinate system is sun oriented
11604 Albedo: <value> Solar declination : <value>
11605 Periapsis angle : <value>
11606 Orbit inclination: <value> Orbit eccentricity: <value>
11607 Semimajor axis ratio: <value> Angle from local noon to orbit ascending node: <value> Orbit period: <value>
11608 Number of subintervals : <number>
11609 Initial time : <value> Initial Theta : <value> Final Theta : <value>
11610 Rotation order is: <name>
11611 Rotation angles X, Y, Z: <value> <value> <value>
11612 Rotation angle increments for one orbit: <value> <value> <value>
11613 Rotation angles with time are: 1X
11614 Sun angles 1X
11615 Thetas=<value> Phis=<value> Time=<value> at orbit theta=<value>
11616 Planet angles 1X
11617 Hr ratio=<value> Thetae=<value> Phie=<value> Time=<value>
11618 Element elimination information
11619 Element <ID> <name> <value> Cap=<value> RC=<value> Gsum=<value>
11620 Element <ID> <name> <value> Cap=<value> RC=<value> Gsum=<value>
11621 Name assignment report Name First element Last element Increment
11622 <string> <integer> <integer> <integer>
11623 Beta - angle between orbit plane and sun vector (degrees): <value>
11624 Element assignment list for cubic space elements
11625 <string> <List of integers>
11626 Element <ID> was transformed into the reverse side of element <ID>
11627 List of surface coated elements
11628 Element <ID> was coated with: <ID> <ID> <ID> <ID> <ID> <ID>
11629 MAT Cards created from combining OPTICAL and MAT Cards New MAT Card Old MAT Card Front OPTICAL Card Reverse OPTICAL Card
11630 <integer> <integer> <integer> <integer>
11631 <string>
11632 Card 9 PARAMS Cards
11633 STREAM <ID>: <name> creates <integer> elements
11634 <integer> <integer> <integer> <integer> <integer> <integer> <integer> <integer> <integer> <integer>
11635 VOID <ID>: <name> creates element <ID>
11636 The following 1D fluid flow elements were created for the following Stream BC's:
11637 The following void elements were created for the following void BC's:
11638 The following fluid flow elements were created for the following Convecting Zone BC's:
11639 CONVECTING ZONE <ID>: <name> creates <ID> elements
11640 The following <integer> MAT Card conversion(s) enabled:
11641 -MAT Card <integer> converts to MAT Card <integer> when <type> > <value>
11801 Echo of input data
11802 Element <ID> <ID>
11803 Node <ID> X=<value> Y=<value> Z=<value>
11804 Surface normal is X=<value> Y=<value> Z=<value> C.G. is at X=<value> Y=<value> Z=<value> El. center is at X=<value> Y=<value> Z=<value> Area =<value> Infrared emissivity=<value> Solar absorptivity =<value>
11805 Unit axis vector X=<value> Y=<value> Z=<value> C.G. is at X=<value> Y=<value> Z=<value> El. center is at X=<value> Y=<value> Z=<value> Area =<value> Infrared emissivity=<value> Solar absorptivity =<value>
11806 Solar transmissivity <value>
11807 Cond.*Thickness =<value>
11808 Cond*X-section area=<value>
11809 <value> Cap. per unit area =<value>
11810 Cap. per unit lngth=<value>
11811 Capacitance =<value>
11812 Area factor =<value> Diameter =<value>
11813 Capacitance =<value>
11814 Length =<value>
11815 Spec. reflectivity =<value>
11816 <value> C.G. is at X=<value> Y=<value> Z=<value> El. center is at X=<value> Y=<value> Z=<value> Volume =<value> Thermal cond. =<value> Specific heat =<value> Capacitance =<value>
11817 This is a circular element
11818 Calculating model terms for articulation time step <integer>
11819 Patch <integer>:<integer> elements merged to <integer> list: <List of integers>
11820 Summary of patch creation for view factor calculations:
11821 Rotation angles 1X
11822 Rotation angle=<value> Time=<value>
12801 CONDN found non-zero net mass flow into the solid element.
12802 Element: <ID> net mass flow: <value>
13401 Hemiview found inactive faces that are seen by other elements.
13402 See group: <name> in groups.unv.
13403 Emitter element and the inactive face it sees:
13404 Element: <ID> sees rev. side of: <ID>
13405 Interface Elements : <List of IDs>
13406 While processing the radiation request <number> inactive faces (back of element without optical properties) seen by other elements were detected. Here is the list of elements: <List of IDs>