canBeImplementedWith
P8649
predicate
Indicates that one entity is capable of being realized, executed, or fulfilled through the use or application of another entity.
All labels observed (21)
| Label | Occurrences |
|---|---|
| mayBeImplementedAs | 34 |
| hasImplementationIn | 26 |
| canBeImplementedAs | 25 |
| canBeImplementedBy | 20 |
| canBeGeneratedBy | 17 |
| implementsAlgorithm | 17 |
| canBeImplementedWith canonical | 16 |
| canBeInstantiatedWith | 7 |
| hasImplementationLanguage | 7 |
| mayBeImplementedBy | 3 |
| canBeBuiltFrom | 2 |
| canBeDefinedUsing | 2 |
| canBeImplementedOver | 2 |
| canBeImplementedThrough | 2 |
| canBePolyfilledBy | 2 |
| canBeRealizedWith | 2 |
| potentiallyImplementedBy | 2 |
| WSGIImplementation | 1 |
| areImplementedVia | 1 |
| canBePolyfilled | 1 |
| customRulesImplementedWith | 1 |
Description generation (PDg)
The one-sentence description above was generated by prompting gpt-5.1 with the predicate name and this instruction.
Instruction
Given a predicate that represents a relationship or action between entities, generate a one-sentence description explaining its meaning. # Instructions Focus on describing the relationship, not the entities themselves. # Response Format Begin the description with \' Indicates...\'
Input
Predicate: canBeImplementedWith
Generated description
Indicates that one entity is capable of being realized, executed, or fulfilled through the use or application of another entity.
Sample triples (190)
| Subject | Object |
|---|---|
| negative feedback amplifier | operational amplifier ⓘ |
| negative feedback amplifier | bipolar junction transistor amplifier ⓘ |
| negative feedback amplifier | field-effect transistor amplifier ⓘ |
| negative feedback amplifier | vacuum tube amplifier ⓘ |
| iSCSI | software initiator via predicate surface "canBeImplementedAs" ⓘ |
| iSCSI | hardware offload adapter via predicate surface "canBeImplementedAs" ⓘ |
| Probabilistic Encryption | trapdoor permutations via predicate surface "canBeBuiltFrom" ⓘ |
| Probabilistic Encryption | one-way functions with hard-core predicates via predicate surface "canBeBuiltFrom" ⓘ |
| OpenAI Baselines |
Atari deep Q-network
via predicate surface "implementsAlgorithm"
ⓘ
surface form:
Deep Q-Network
|
| OpenAI Baselines |
Atari deep Q-network
via predicate surface "implementsAlgorithm"
ⓘ
surface form:
DQN
|
| OpenAI Baselines | Double DQN via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | Dueling DQN via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | Prioritized Experience Replay DQN via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | A2C via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | A3C via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | ACKTR via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | PPO via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | PPO2 via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | TRPO via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines | DDPG via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines |
Her
via predicate surface "implementsAlgorithm"
ⓘ
surface form:
HER
|
| OpenAI Baselines | GAIL via predicate surface "implementsAlgorithm" ⓘ |
| OpenAI Baselines |
DDPG
via predicate surface "implementsAlgorithm"
ⓘ
surface form:
Deep Deterministic Policy Gradient
|
| OpenAI Baselines | Hindsight Experience Replay via predicate surface "implementsAlgorithm" ⓘ |
| Flask |
Flask
via predicate surface "WSGIImplementation"
self-linksurface differs
ⓘ
surface form:
Werkzeug
|
| Schematron | XSLT transformations via predicate surface "canBeImplementedBy" ⓘ |
| Fraunhofer diffraction | collimating lens via predicate surface "canBeRealizedWith" ⓘ |
| Fraunhofer diffraction | focusing lens via predicate surface "canBeRealizedWith" ⓘ |
| MathML | LaTeX-to-MathML converters via predicate surface "canBeGeneratedBy" ⓘ |
| MathML | computer algebra systems via predicate surface "canBeGeneratedBy" ⓘ |
| Cyclone | C via predicate surface "hasImplementationLanguage" ⓘ |
| Harvard architecture | strict Harvard architecture via predicate surface "canBeImplementedAs" ⓘ |
| Harvard architecture | modified Harvard architecture via predicate surface "canBeImplementedAs" ⓘ |
| R | C via predicate surface "hasImplementationLanguage" ⓘ |
| R | Fortran via predicate surface "hasImplementationLanguage" ⓘ |
| R | R via predicate surface "hasImplementationLanguage" self-link ⓘ |
| R |
C++
via predicate surface "hasImplementationLanguage"
ⓘ
surface form:
Rcpp (C++ interface)
|
| ISO standards | certification (for certifiable standards) via predicate surface "areImplementedVia" ⓘ |
| WebAssembly.instantiateStreaming | fetch + WebAssembly.instantiate with ArrayBuffer via predicate surface "canBePolyfilledBy" ⓘ |
| WebAssembly.compileStreaming | fetch + WebAssembly.compile via predicate surface "canBePolyfilledBy" ⓘ |
| Acts of Tynwald | secondary legislation via predicate surface "mayBeImplementedBy" ⓘ |
| Automatic Train Supervision | centralized architecture via predicate surface "mayBeImplementedAs" ⓘ |
| Automatic Train Supervision | distributed architecture via predicate surface "mayBeImplementedAs" ⓘ |
| Command | function objects or functors ⓘ |
| Command | callbacks ⓘ |
| Command | lambda expressions ⓘ |
|
State
surface form:
State (design pattern)
|
interfaces ⓘ |
|
State
surface form:
State (design pattern)
|
abstract classes ⓘ |
| Boo | C# via predicate surface "hasImplementationLanguage" ⓘ |
| ODBC Driver Manager |
ODBC Driver Manager
via predicate surface "canBeImplementedBy"
self-linksurface differs
ⓘ
surface form:
Microsoft ODBC Driver Manager
|