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https://github.com/GrammaticalFramework/gf-core.git
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139 lines
4.8 KiB
OpenEdge ABL
139 lines
4.8 KiB
OpenEdge ABL
fof(axengineeringLem0, axiom,
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( ! [Var_MODELING] :
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(hasType(type_Modeling, Var_MODELING) =>
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(( ? [Var_MODEL] :
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(hasType(type_Model, Var_MODEL) &
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(f_result(Var_MODELING,Var_MODEL)))))))).
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fof(axengineeringLem1, axiom,
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( ! [Var_MODELING] :
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(hasType(type_MultipoleModeling, Var_MODELING) =>
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(( ? [Var_MODEL] :
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(hasType(type_MultipoleModel, Var_MODEL) &
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(f_result(Var_MODELING,Var_MODEL)))))))).
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fof(axengineeringLem2, axiom,
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( ! [Var_POLE] :
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(hasType(type_MultipolePole, Var_POLE) =>
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(( ! [Var_MULTIPOLE] :
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(hasType(type_Abstract, Var_MULTIPOLE) =>
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(((f_abstractPart(Var_POLE,Var_MULTIPOLE)) => (( ? [Var_SECTION] :
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(hasType(type_MultipoleSection, Var_SECTION) &
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(((f_abstractPart(Var_POLE,Var_SECTION)) & (f_abstractPart(Var_SECTION,Var_MULTIPOLE))))))))))))))).
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fof(axengineeringLem3, axiom,
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( ! [Var_DTHROUGH] :
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(hasType(type_PhysicalDimension, Var_DTHROUGH) =>
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(( ! [Var_DACROSS] :
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(hasType(type_PhysicalDimension, Var_DACROSS) =>
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(( ! [Var_QTHROUGH] :
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(hasType(type_MultipoleQuantity, Var_QTHROUGH) =>
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(( ! [Var_QACROSS] :
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(hasType(type_MultipoleQuantity, Var_QACROSS) =>
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(( ! [Var_THROUGH] :
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(hasType(type_MultipoleVariable, Var_THROUGH) =>
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(( ! [Var_ACROSS] :
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(hasType(type_MultipoleVariable, Var_ACROSS) =>
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(( ! [Var_POLE] :
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(hasType(type_MultipolePole, Var_POLE) =>
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(((((f_hasAcrossVariable(Var_POLE,Var_ACROSS)) & (((f_hasThroughVariable(Var_POLE,Var_THROUGH)) & (((f_hasVariable(Var_QACROSS,Var_ACROSS)) & (((f_hasVariable(Var_QTHROUGH,Var_THROUGH)) & (((f_hasDimension(Var_QACROSS,Var_DACROSS)) & (f_hasDimension(Var_QTHROUGH,Var_DTHROUGH)))))))))))) => (( ? [Var_DOMAIN] :
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(hasType(type_PhysicalDomain, Var_DOMAIN) &
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(f_physicalDomain(Var_DACROSS,Var_DTHROUGH,Var_DOMAIN)))))))))))))))))))))))))))).
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fof(axengineeringLem4, axiom,
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( ! [Var_MULTIPOLE] :
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(hasType(type_Multipole, Var_MULTIPOLE) =>
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(( ? [Var_SECTION] :
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(hasType(type_MultipoleSection, Var_SECTION) &
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(f_abstractPart(Var_SECTION,Var_MULTIPOLE)))))))).
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fof(axengineeringLem5, axiom,
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( ! [Var_SECTION] :
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(hasType(type_MultipoleSection, Var_SECTION) =>
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(( ? [Var_POLE1] :
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(hasType(type_MultipolePole, Var_POLE1) &
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(( ? [Var_POLE2] :
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(hasType(type_MultipolePole, Var_POLE2) &
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(((f_abstractPart(Var_POLE1,Var_SECTION)) & (((f_abstractPart(Var_POLE2,Var_SECTION)) & (Var_POLE1 != Var_POLE2)))))))))))))).
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fof(axengineeringLem6, axiom,
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( ! [Var_PORT] :
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(hasType(type_MultipolePort, Var_PORT) =>
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(( ? [Var_POLE1] :
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(hasType(type_MultipolePole, Var_POLE1) &
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(( ? [Var_POLE2] :
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(hasType(type_MultipolePole, Var_POLE2) &
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(( ? [Var_POLE3] :
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(hasType(type_MultipolePole, Var_POLE3) &
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(((f_abstractPart(Var_POLE1,Var_PORT)) & (((f_abstractPart(Var_POLE2,Var_PORT)) & (((f_abstractPart(Var_POLE3,Var_PORT)) & (((Var_POLE1 = Var_POLE2) & (((Var_POLE2 = Var_POLE3) & (Var_POLE1 = Var_POLE3))))))))))))))))))))))).
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fof(axengineeringLem7, axiom,
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( ! [Var_M] :
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(hasType(type_AcrossVariableAccumulator, Var_M) =>
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(( ? [Var_C] :
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(hasType(type_CapacitorElement, Var_C) &
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(f_represents(Var_M,Var_C)))))))).
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fof(axengineeringLem8, axiom,
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( ! [Var_M] :
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(hasType(type_ElectricalTwopole, Var_M) =>
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(( ! [Var_E] :
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(hasType(type_Entity, Var_E) =>
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(( ? [Var_C] :
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(hasType(type_CapacitorElement, Var_C) &
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(f_represents(Var_M,Var_E))))))))))).
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fof(axengineeringLem9, axiom,
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( ! [Var_M] :
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(hasType(type_ThroughVariableAccumulator, Var_M) =>
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(( ? [Var_I] :
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(hasType(type_InductorElement, Var_I) &
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(f_represents(Var_M,Var_I)))))))).
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fof(axengineeringLem10, axiom,
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( ! [Var_M] :
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(hasType(type_ElectricalTwopole, Var_M) =>
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(( ! [Var_I] :
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(hasType(type_Entity, Var_I) =>
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(( ? [Var_C] :
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(hasType(type_InductorElement, Var_C) &
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(f_represents(Var_M,Var_I))))))))))).
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fof(axengineeringLem11, axiom,
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( ! [Var_M] :
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(hasType(type_Twoport, Var_M) =>
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(( ? [Var_T] :
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(hasType(type_Transducer, Var_T) &
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(f_represents(Var_M,Var_T)))))))).
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fof(axengineeringLem12, axiom,
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( ! [Var_M] :
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(hasType(type_Dissipator, Var_M) =>
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(( ? [Var_R] :
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(hasType(type_ResistorElement, Var_R) &
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(f_represents(Var_M,Var_R)))))))).
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fof(axengineeringLem13, axiom,
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( ! [Var_M] :
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(hasType(type_ElectricalTwopole, Var_M) =>
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(( ? [Var_R] :
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(hasType(type_ResistorElement, Var_R) &
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(f_represents(Var_M,Var_R)))))))).
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fof(axengineeringLem14, axiom,
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( ! [Var_PS] :
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(hasType(type_PowerSource, Var_PS) =>
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(( ? [Var_RE] :
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(hasType(type_RadiatingElectromagnetic, Var_RE) &
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(f_origin(Var_RE,Var_PS)))))))).
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fof(axengineeringLem15, axiom,
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( ! [Var_PROCESS] :
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(hasType(type_ITProcess, Var_PROCESS) =>
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(( ? [Var_AGENT] :
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(hasType(type_ITAgent, Var_AGENT) &
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(( ? [Var_PATIENT] :
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(hasType(type_Computer, Var_PATIENT) &
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(((f_agent(Var_PROCESS,Var_AGENT)) & (f_patient(Var_PROCESS,Var_PATIENT))))))))))))).
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