hasTradeoff
P28908
predicate
Indicates that one option or outcome involves a compromise in which gaining certain benefits requires accepting corresponding costs or disadvantages.
All labels observed (8)
| Label | Occurrences |
|---|---|
| tradeOff | 54 |
| tradeoff | 22 |
| hasTradeoff canonical | 7 |
| tradeOffs | 5 |
| tradesOff | 4 |
| balanceTradeoff | 3 |
| strategicTradeoff | 2 |
| isTradeOffBetween | 1 |
Sample triples (98)
| Subject | Object |
|---|---|
| OWL Full | expressivity versus decidability ⓘ |
| Blitzscaling | efficiency for speed via predicate surface "tradeoff" ⓘ |
| Blitzscaling | short-term profitability for long-term scale via predicate surface "tradeoff" ⓘ |
| BRIN | lower index size vs less precise lookups via predicate surface "tradeoff" ⓘ |
| Prioritized Experience Replay DQN | focus on rare high-error transitions vs coverage of state space via predicate surface "tradeOff" ⓘ |
| OWL 2 RL | reduced expressivity for better scalability ⓘ |
| Intel SpeedStep | reduced performance at lower frequencies via predicate surface "tradeOff" ⓘ |
| Composite | can make design overly general for simple structures via predicate surface "tradeoff" ⓘ |
| Composite | can make it harder to restrict components in a composite via predicate surface "tradeoff" ⓘ |
| Flyweight | increased complexity in state management via predicate surface "tradeoff" ⓘ |
| Flyweight | client must manage extrinsic state via predicate surface "tradeoff" ⓘ |
|
State
surface form:
State (design pattern)
|
increases number of classes via predicate surface "tradeoff" ⓘ |
| RISC architecture | more instructions per program compared to CISC via predicate surface "tradeOff" ⓘ |
| RISC architecture | simpler individual instructions via predicate surface "tradeOff" ⓘ |
| TLC (triple-level cell) | higher capacity versus lower endurance via predicate surface "tradeOff" ⓘ |
| TLC (triple-level cell) | lower cost per gigabyte versus reduced write performance via predicate surface "tradeOff" ⓘ |
| classical fourth-order Runge–Kutta method | accuracy and computational cost via predicate surface "isTradeOffBetween" ⓘ |
| Thumb instruction set | reduced instruction encoding space for improved code density via predicate surface "tradeOff" ⓘ |
| Thumb instruction set | fewer available registers in many instructions compared to ARM state via predicate surface "tradeOff" ⓘ |
| Serial GC | longer pause times for simplicity via predicate surface "tradeOff" ⓘ |
| Serial GC | throughput over pause-time optimization via predicate surface "tradeOff" ⓘ |
| Shenandoah GC | higher CPU overhead for lower pause times via predicate surface "tradeOff" ⓘ |
| Ramsey pricing | efficiency versus distributional equity via predicate surface "tradeOff" ⓘ |
| theta-method | stability versus numerical damping controlled by theta via predicate surface "tradeOffs" ⓘ |
| theta-method | accuracy versus stability controlled by theta via predicate surface "tradeOffs" ⓘ |
| oblivious RAM | performance vs privacy via predicate surface "tradeOff" ⓘ |
| Block Range Index | less precise than B-tree indexes via predicate surface "tradeOff" ⓘ |
| Block Range Index | may scan more pages than B-tree via predicate surface "tradeOff" ⓘ |
| GIN index | slower writes compared to B-tree indexes via predicate surface "tradeOff" ⓘ |
| GIN index | larger index size compared to B-tree indexes via predicate surface "tradeOff" ⓘ |
| SIV misuse-resistant AEAD | higher computational cost than non-misuse-resistant AEAD via predicate surface "tradeOff" ⓘ |
| flat fare (Washington Metro) | reduced price differentiation by distance via predicate surface "tradeOff" ⓘ |
| flat fare (Washington Metro) | potential cross-subsidy between short and long trips via predicate surface "tradeOff" ⓘ |
| Monte Carlo localization | accuracy versus computational cost via predicate surface "tradeOff" ⓘ |
| S3 Glacier Flexible Retrieval | low storage cost vs higher retrieval latency via predicate surface "tradeoff" ⓘ |
| S3 Glacier Flexible Retrieval | low storage cost vs retrieval fees via predicate surface "tradeoff" ⓘ |
| LDAC | higher bitrate for improved audio quality via predicate surface "tradeoff" ⓘ |
| Hamming window | lower sidelobe levels than rectangular window via predicate surface "tradeOffs" ⓘ |
| Hamming window | wider mainlobe than rectangular window via predicate surface "tradeOffs" ⓘ |
| Hamming window | higher frequency resolution loss than rectangular window via predicate surface "tradeOffs" ⓘ |
| GPT-4.1-mini | lower cost and latency vs peak capability of larger GPT-4.1 models via predicate surface "tradeoff" ⓘ |
| Gemini 2.0 Flash | higher speed with somewhat lower peak capability than largest Gemini models via predicate surface "tradeoff" ⓘ |
| IPsec over TCP | increased overhead compared to native IPsec via predicate surface "tradeOff" ⓘ |
| IPsec over TCP | potential TCP-over-TCP performance issues via predicate surface "tradeOff" ⓘ |
| LPWAN | low data rate for extended range via predicate surface "tradeOff" ⓘ |
| LPWAN | low data rate for low power consumption via predicate surface "tradeOff" ⓘ |
|
NR reduced capability (NR RedCap)
surface form:
NR reduced capability
|
reduced peak data rate via predicate surface "tradeOff" ⓘ |
|
NR reduced capability (NR RedCap)
surface form:
NR reduced capability
|
reduced feature set compared to full-capability NR UE via predicate surface "tradeOff" ⓘ |
| HARQ | increased latency due to retransmissions via predicate surface "tradeoff" ⓘ |
| HARQ | increased receiver complexity via predicate surface "tradeoff" ⓘ |