Ontology type: schema:MonetaryGrant

2012-2016

800000 CNY

Quantum computation and quantum information is a field that is rapidly developing. One of the core of this field is developing quantum algorithms. What kind of problems can a quantum computer solve once it is realized? How to simulate physical systems efficiently using a quantum computer? These are the questions that we are going to answer. In this project, we plan to develop new quantum algorithms using principles of physics, and develop new quantum simulation algorithms as well as the corresponding softwares. In addition, we will develop quantum algorithms for solving problems in discrete mathematics, and study the way to introduce non-linearity in quantum computing in order to solve more complicated problems. Another project we plan to do is measurement-based quantum computation. In this model, universal quantum computing is realized by preparing the ground state of the AKLT Hamiltonian as the initial state and performing single-qubit operations. Therefore, such a quantum state is stable and can be prepared through a cooling procedure. Based on this model, large-scale quantum computing is possible. We plan to perform quantum simulation of the AKLT model and develop quantum algorithms based on this model for universal quantum computing. Using the technique of hybrid quantum computing, we plan to use the advant More... »

JSON-LD is the **canonical representation** for SciGraph data.

TIP: You can open this SciGraph record using an external JSON-LD service: JSON-LD Playground Google SDTT

```
[
{
"@context": "https://springernature.github.io/scigraph/jsonld/sgcontext.json",
"about": [
{
"id": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/2208",
"inDefinedTermSet": "http://purl.org/au-research/vocabulary/anzsrc-for/2008/",
"type": "DefinedTerm"
}
],
"amount": {
"currency": "CNY",
"type": "MonetaryAmount",
"value": "800000"
},
"description": "Quantum computation and quantum information is a field that is rapidly developing. One of the core of this field is developing quantum algorithms. What kind of problems can a quantum computer solve once it is realized? How to simulate physical systems efficiently using a quantum computer? These are the questions that we are going to answer. In this project, we plan to develop new quantum algorithms using principles of physics, and develop new quantum simulation algorithms as well as the corresponding softwares. In addition, we will develop quantum algorithms for solving problems in discrete mathematics, and study the way to introduce non-linearity in quantum computing in order to solve more complicated problems. Another project we plan to do is measurement-based quantum computation. In this model, universal quantum computing is realized by preparing the ground state of the AKLT Hamiltonian as the initial state and performing single-qubit operations. Therefore, such a quantum state is stable and can be prepared through a cooling procedure. Based on this model, large-scale quantum computing is possible. We plan to perform quantum simulation of the AKLT model and develop quantum algorithms based on this model for universal quantum computing. Using the technique of hybrid quantum computing, we plan to use the advant",
"endDate": "2016-12-30T00:00:00Z",
"funder": {
"id": "https://www.grid.ac/institutes/grid.419696.5",
"type": "Organization"
},
"id": "sg:grant.7187794",
"identifier": [
{
"name": "dimensions_id",
"type": "PropertyValue",
"value": [
"7187794"
]
},
{
"name": "nsfc_id",
"type": "PropertyValue",
"value": [
"11275145"
]
}
],
"inLanguage": [
"zh"
],
"keywords": [
"question",
"kind",
"hybrid quantum computing",
"initial state",
"model",
"quantum computer",
"physics",
"problem",
"order",
"software",
"advant",
"measurements",
"universal quantum computing",
"field",
"physical systems",
"quantum algorithms",
"technique",
"quantum states",
"quantum computation",
"new quantum simulation algorithms",
"large-scale quantum computing",
"single-qubit operations",
"quantum information",
"ground state",
"AKLT model",
"quantum computing",
"complicated problem",
"AKLT Hamiltonian",
"cooling procedure",
"quantum simulation",
"discrete mathematics",
"principle",
"core",
"way",
"project",
"new quantum algorithms",
"addition",
"Measurement-Based Quantum Computations"
],
"name": "Quantum Algorithms and Measurement-Based Quantum Computations",
"recipient": [
{
"id": "https://www.grid.ac/institutes/grid.43169.39",
"type": "Organization"
},
{
"affiliation": {
"id": "https://www.grid.ac/institutes/grid.43169.39",
"name": "Xi'an Jiaotong University",
"type": "Organization"
},
"familyName": "Wang",
"givenName": "He Feng",
"id": "sg:person.011551735160.54",
"type": "Person"
},
{
"member": "sg:person.011551735160.54",
"roleName": "PI",
"type": "Role"
}
],
"sameAs": [
"https://app.dimensions.ai/details/grant/grant.7187794"
],
"sdDataset": "grants",
"sdDatePublished": "2019-03-07T12:45",
"sdLicense": "https://scigraph.springernature.com/explorer/license/",
"sdPublisher": {
"name": "Springer Nature - SN SciGraph project",
"type": "Organization"
},
"sdSource": "s3://com.uberresearch.data.processor/core_data/20181219_192338/projects/base/nsfc_projects_7.xml.gz",
"startDate": "2012-12-31T00:00:00Z",
"type": "MonetaryGrant",
"url": "http://npd.nsfc.gov.cn/projectDetail.action?pid=11275145"
}
]
```

Download the RDF metadata as: json-ld nt turtle xml License info

JSON-LD is a popular format for linked data which is fully compatible with JSON.

curl -H 'Accept: application/ld+json' 'https://scigraph.springernature.com/grant.7187794'

N-Triples is a line-based linked data format ideal for batch operations.

curl -H 'Accept: application/n-triples' 'https://scigraph.springernature.com/grant.7187794'

Turtle is a human-readable linked data format.

curl -H 'Accept: text/turtle' 'https://scigraph.springernature.com/grant.7187794'

RDF/XML is a standard XML format for linked data.

curl -H 'Accept: application/rdf+xml' 'https://scigraph.springernature.com/grant.7187794'

This table displays all metadata directly associated to this object as RDF triples.

82 TRIPLES
19 PREDICATES
60 URIs
52 LITERALS
5 BLANK NODES

Subject | Predicate | Object | |
---|---|---|---|

1 | sg:grant.7187794 | schema:about | anzsrc-for:2208 |

2 | ″ | schema:amount | N184931c42aff45818da124bed3588101 |

3 | ″ | schema:description | Quantum computation and quantum information is a field that is rapidly developing. One of the core of this field is developing quantum algorithms. What kind of problems can a quantum computer solve once it is realized? How to simulate physical systems efficiently using a quantum computer? These are the questions that we are going to answer. In this project, we plan to develop new quantum algorithms using principles of physics, and develop new quantum simulation algorithms as well as the corresponding softwares. In addition, we will develop quantum algorithms for solving problems in discrete mathematics, and study the way to introduce non-linearity in quantum computing in order to solve more complicated problems. Another project we plan to do is measurement-based quantum computation. In this model, universal quantum computing is realized by preparing the ground state of the AKLT Hamiltonian as the initial state and performing single-qubit operations. Therefore, such a quantum state is stable and can be prepared through a cooling procedure. Based on this model, large-scale quantum computing is possible. We plan to perform quantum simulation of the AKLT model and develop quantum algorithms based on this model for universal quantum computing. Using the technique of hybrid quantum computing, we plan to use the advant |

4 | ″ | schema:endDate | 2016-12-30T00:00:00Z |

5 | ″ | schema:funder | https://www.grid.ac/institutes/grid.419696.5 |

6 | ″ | schema:identifier | N47e8814b9c564508b4b58e00a39cfeb7 |

7 | ″ | ″ | Na751f23ad7fe4db4a501f5f292fe5d0e |

8 | ″ | schema:inLanguage | zh |

9 | ″ | schema:keywords | AKLT Hamiltonian |

10 | ″ | ″ | AKLT model |

11 | ″ | ″ | Measurement-Based Quantum Computations |

12 | ″ | ″ | addition |

13 | ″ | ″ | advant |

14 | ″ | ″ | complicated problem |

15 | ″ | ″ | cooling procedure |

16 | ″ | ″ | core |

17 | ″ | ″ | discrete mathematics |

18 | ″ | ″ | field |

19 | ″ | ″ | ground state |

20 | ″ | ″ | hybrid quantum computing |

21 | ″ | ″ | initial state |

22 | ″ | ″ | kind |

23 | ″ | ″ | large-scale quantum computing |

24 | ″ | ″ | measurements |

25 | ″ | ″ | model |

26 | ″ | ″ | new quantum algorithms |

27 | ″ | ″ | new quantum simulation algorithms |

28 | ″ | ″ | order |

29 | ″ | ″ | physical systems |

30 | ″ | ″ | physics |

31 | ″ | ″ | principle |

32 | ″ | ″ | problem |

33 | ″ | ″ | project |

34 | ″ | ″ | quantum algorithms |

35 | ″ | ″ | quantum computation |

36 | ″ | ″ | quantum computer |

37 | ″ | ″ | quantum computing |

38 | ″ | ″ | quantum information |

39 | ″ | ″ | quantum simulation |

40 | ″ | ″ | quantum states |

41 | ″ | ″ | question |

42 | ″ | ″ | single-qubit operations |

43 | ″ | ″ | software |

44 | ″ | ″ | technique |

45 | ″ | ″ | universal quantum computing |

46 | ″ | ″ | way |

47 | ″ | schema:name | Quantum Algorithms and Measurement-Based Quantum Computations |

48 | ″ | schema:recipient | N78435bba903c443aa0cc531491b94870 |

49 | ″ | ″ | sg:person.011551735160.54 |

50 | ″ | ″ | https://www.grid.ac/institutes/grid.43169.39 |

51 | ″ | schema:sameAs | https://app.dimensions.ai/details/grant/grant.7187794 |

52 | ″ | schema:sdDatePublished | 2019-03-07T12:45 |

53 | ″ | schema:sdLicense | https://scigraph.springernature.com/explorer/license/ |

54 | ″ | schema:sdPublisher | N316656ebecd04ccbb01832b2cdc8787f |

55 | ″ | schema:startDate | 2012-12-31T00:00:00Z |

56 | ″ | schema:url | http://npd.nsfc.gov.cn/projectDetail.action?pid=11275145 |

57 | ″ | sgo:license | sg:explorer/license/ |

58 | ″ | sgo:sdDataset | grants |

59 | ″ | rdf:type | schema:MonetaryGrant |

60 | N184931c42aff45818da124bed3588101 | schema:currency | CNY |

61 | ″ | schema:value | 800000 |

62 | ″ | rdf:type | schema:MonetaryAmount |

63 | N316656ebecd04ccbb01832b2cdc8787f | schema:name | Springer Nature - SN SciGraph project |

64 | ″ | rdf:type | schema:Organization |

65 | N47e8814b9c564508b4b58e00a39cfeb7 | schema:name | nsfc_id |

66 | ″ | schema:value | 11275145 |

67 | ″ | rdf:type | schema:PropertyValue |

68 | N78435bba903c443aa0cc531491b94870 | schema:member | sg:person.011551735160.54 |

69 | ″ | schema:roleName | PI |

70 | ″ | rdf:type | schema:Role |

71 | Na751f23ad7fe4db4a501f5f292fe5d0e | schema:name | dimensions_id |

72 | ″ | schema:value | 7187794 |

73 | ″ | rdf:type | schema:PropertyValue |

74 | anzsrc-for:2208 | schema:inDefinedTermSet | anzsrc-for: |

75 | ″ | rdf:type | schema:DefinedTerm |

76 | sg:person.011551735160.54 | schema:affiliation | https://www.grid.ac/institutes/grid.43169.39 |

77 | ″ | schema:familyName | Wang |

78 | ″ | schema:givenName | He Feng |

79 | ″ | rdf:type | schema:Person |

80 | https://www.grid.ac/institutes/grid.419696.5 | ″ | schema:Organization |

81 | https://www.grid.ac/institutes/grid.43169.39 | schema:name | Xi'an Jiaotong University |

82 | ″ | rdf:type | schema:Organization |