Relation pm#reflexive_relation__reflexiverelation (?,?) this category only serves structuration purposes: it is instance of pm#reflexive_relation_type which is not instance of pm#class_of_inheritable_relation_type
supertype: binary_relation_with_particular_mathematical_property
instance of: reflexive_relation_type
subtype: equivalence_relation__equivalencerelation (?,?) this category only serves structuration purposes: it is instance of pm#equivalence_relation_type which is not instance of pm#class_of_inheritable_relation_type
subtype: similar (?,?) DO NOT USE SUCH A RELATION TYPE DIRECTLY
subtype: closely_similar__closelysimilar (?,?) the '~' link in WebKB-2: currently only used between categories for Greek gods and their Roman counterparts, and between some types from the 3D (endurantist) approach and their counterparts from the 4D (perdurantist) approach or the ?D (vague/unspecified) approach)
subtype: loosely_similar__looselysimilar (?,?)
subtype: related_to__relatedto (?,?) the '&' link in WebKB-2 (currently used for representing a sumo#related_internal_concept relation)
subtype: related_internal_concept (?,?) the two arguments are related concepts within the SUMO, i.e. there is a significant similarity of meaning between them; to indicate a meaning relation between a SUMO concept and a concept from another source, use sumo#related_external_concept
subtype: equal (?,?) "=" in KIF; true if the 1st argument is identical to the 2nd
subtype: same_as (?,?) MORE PRECISE TYPES THAN THIS ONE SHOULD BE USED
subtype: same_type_as (type,type)
subtype: equivalent_class (class,class) in WebKB, use the link '='
subtype: equivalent_property (binary_relation_type,binary_relation_type) in WebKB, use the link '='
subtype: same_individual_as (?,?)
subtype: equivalence__equivalentTo___iff__iff (description,description)
subtype: copy (object,object) relates an object to an exact copy of the object, where an exact copy is indistinguishable from the original with regard to every property except (possibly) spatial and/or temporal location
subtype: equivalent_content_class (?,?)
subtype: equivalent_content_instance (?,?)
subtype: cooccur (?,?)
subtype: family_relation (?,?)
subtype: partial_ordering_relation (?,?) this category only serves structuration purposes: it is instance of pm#partial_ordering_relation_type which is not instance of pm#class_of_inheritable_relation_type
subtype: total_ordering_relation (?,?) this category only serves structuration purposes: it is instance of pm#total_ordering_relation_type which is not instance of pm#class_of_inheritable_relation_type
subtype: inferior_to__less_than___superior__superior (?,?) fuzzy category, DO NOT USE DIRECTLY
subtype: superior_to__more_than___inferior__inferior (?,?) fuzzy category, DO NOT USE DIRECTLY
subtype: before (time_measure,time_measure)
subtype: after (time_measure,time_measure)
subtype: before_location__before (spatial_object,spatial_object)
subtype: inferior_or_equal_to__less_than_or_equal_to___superior_or_equal___maximum__maximum (?,?) fuzzy category, DO NOT USE DIRECTLY
subtype: superior_or_equal_to__more_than_or_equal_to___inferior_or_equal___minimum__minimum (?,?) fuzzy category, DO NOT USE DIRECTLY
subtype: generalizing_type (?,type) fuzzy category, DO NOT USE DIRECTLY
subtype: supertype (type,type) in the FT notation, the '<' link is only used to connect to a "strict" supertype
subtype: sub_class_of__subclassof__super_class__superclas (class,class) in WebKB, use the link '<'
subtype: subrelation (relation_type,relation_type) if the common reading conventions of parameters had been respected, this type would have been named subclass_of; every tuple of the 1st argument (r1) is also a tuple of the 2nd argument (r2), i.e. if r1 holds for some arguments arg_1, arg_2, ... arg_n, then the r2 holds for the same arguments; a consequence of this is that a relation and its subrelations must have the same valence
subtype: sub_property_of (binary_relation_type,binary_relation_type) in WebKB, use the link '<'
subtype: kind__type___class___instance_of__instanceof (?,class) the '^' link in the FT notation
subtype: subclass__subclass_of (set_or_class,set_or_class) if the common reading conventions of parameters had been respected, this type would have been named subclass_of; every instance of the 1st argument is also an instance of the 2nd argument; a class may have multiple superclasses and subclasses
subtype: immediate_subclass__immediate_subclass_of (set_or_class,set_or_class) the 1st argument is a subclass of the 2nd argument and there is no other subclass of the 2nd argument such that the 1st is also a subclass of the 2nd; in WebKB, use the link '<'
subtype: specializing_type (type,?)
subtype: instance (type,?) the ':' link in the FT notation
subtype: subtype__subtype_or_equal (type,type) subtype links should actually be strict subtype links or not much checking can be done
subtype: strict_subtype (type,type) the '>' link in the FT notation
subtype: properly_subsumes_leaf__PSBL (type,type) the 2nd type is a leaf type properly subsumed by the 1st type
subtype: subsumes_leaf__SBL (type,type) the 2nd type is a leaf type subsumed by the 1st type
subtype: properly_subsumes_leaf__PSBL (type,type) the 2nd type is a leaf type properly subsumed by the 1st type
subtype: constitution (?,?)
subtype: substance (? -> ?)
subtype: matter (physical_entity -> physical_entity_part_or_substance)
subtype: constituted_by__constitutedby__substance___K__k (entity,entity)
subtype: has_member__hasmember (entity,entity)
subtype: part (?,?)
subtype: sub_situation__subsituation (situation,situation)
subtype: sub_process__subproces (process,process)
subtype: temporal_part__P.T (perdurant,perdurant)
subtype: spatial_part__spatialpart__P.S (perdurant,perdurant)
subtype: spatial_part__spatialpart (spatial_object,spatial_object)
subtype: physical_part (physical_entity,physical_entity)
subtype: sub_collection__subcollection (collection,collection) a partial order relation
subtype: ending_collection (collection,collection)
subtype: final_segment__finalsegment (collection,collection) the second collection is a final segment of the 1st
subtype: sublist__final_segment_of__finalsegmentof (list,list) USE pm#final_segment INSTEAD OF THIS RELATION TYPE; "sublist" is a misleading name; "final_segment_of" is better
subtype: main_part (?,?)
subtype: first_part__firstpart (?,?)
subtype: first (list -> ?)
subtype: first (list -> ?)
subtype: last_part (?,?)
subtype: last (list -> ?)
subtype: part_in_Dolce_Lite (entity,entity)
subtype: part (entity,entity) the subpart may or may not be different from the whole
subtype: component (entity,entity)
subtype: atomic_part (entity,atom) an undivisible part
subtype: temporary_atomic_part__AtP (entity,atom)
subtype: proper_part (entity,entity) the subpart is different from the whole
subtype: temporary_proper_part (endurant,endurant)
subtype: temporary_part__temporarypart (endurant,endurant)
subtype: temporary_component__temporarycomponent (endurant,endurant)
subtype: constant_part (entity,entity)
subtype: sibling_part__siblingpart (entity,entity)
subtype: in_proceedings (conference,publication)
subtype: wnMember (?,?) member relation in WordNet
subtype: member (collection,*)
subtype: domain_object (domain,?)
subtype: core_domain_object__central_object_of_domain (domain,?)
subtype: reverse_of_KIF_member (set,?) this type only exists to make the connection to kif#member (which should have been named kif#member_of to respect the common reading conventions of parameters)
subtype: item (list,?)
subtype: item (list,?) for item(L,I) read: I is an item in L; either first(L,I) or item(R,I) where rest(L,R)
subtype: li (collection,*)
subtype: first (list -> ?)
subtype: last (list -> ?)
subtype: butlast (list -> ?)
subtype: nth (list,positive_integer -> ?)
subtype: sub_collection__subcollection (collection,collection) a partial order relation
subtype: sub_attribute__subattribute (Attribute,Attribute) the second argument can be ascribed to everything which has the first argument ascribed to it
subtype: sub_collection__subcollection__sub_collection_of (collection,collection) the 1st collection is a proper part of the 2nd
subtype: less_than_or_equal_to (?,?)
subtype: greater_than_or_equal_to (?,?)
subtype: sub_list__sublist__sub_list_of (list,list) the 1st argument is a sublist of the 2nd, i.e. every element of the 1st is an element of the 2nd and the elements that are common to both lists have the same order in both lists
subtype: initial_list__initiallist (list,list) the 1st argument (?L1) is a sublist of the 2nd (?L2), and (sumo#list_order_fn ?L1 ?NUMBER) returns the same value as (sumo#list_order_fn ?L2 ?N) for all of the values of ?N over which (sumo#list_order_fn ?L1 ?N) is defined
subtype: initial_list__initiallist (list,list) the 1st argument (?L1) is a sublist of the 2nd (?L2), and (sumo#list_order_fn ?L1 ?NUMBER) returns the same value as (sumo#list_order_fn ?L2 ?N) for all of the values of ?N over which (sumo#list_order_fn ?L1 ?N) is defined
subtype: subsumes_content_class (?,?)
subtype: subsumes_content_instance (?,?)
subtype: temporal_part (?,?)
subtype: before_or_equal (?,?)
subtype: sub_process__subproces (?,?)
subtype: sub_organization__suborganization (?,?)
subtype: geometric_part__geometricpart (?,?)
subtype: overlaps_temporally (?,?)
subtype: connected (object,*)
subtype: overlaps_spatially (?,?)
107 categories printed