Benchmarks: Difference between revisions
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Line 31: | Line 31: | ||
| 20 || ?10 || ?420 || ?1623 | | 20 || ?10 || ?420 || ?1623 | ||
|- | |- | ||
| 50 || 4 || | | 50 || 4 || 209 || ?807 | ||
|- | |- | ||
|100 || ?5 || ?152 || ?529 | |100 || ?5 || ?152 || ?529 |
Revision as of 09:46, 10 February 2010
Benchmark results for CYANA 3.0:
Computer system | Number of processors (cores) | Computation time (s) | ||
Basic | Auto | Test suite | ||
Laptop | 1 | ? | ? | ? |
Desktop (intel) | 1 | ?228 | ? | ? |
4 | 57 | ? | ? | |
Desktop (gfortran) | 1 | ?326 | ? | ? |
4 | ? | ? | ? | |
Mac mini (intel) | 2 | 87 | 4092 | 14977 |
Mac mini (gfortran) | 2 | 104 | ? | ? |
Server | 1 | ?144 | ? | ? |
10 | ?16 | ?762 | ?2997 | |
20 | ?10 | ?420 | ?1623 | |
50 | 4 | 209 | ?807 | |
100 | ?5 | ?152 | ?529 |
February 2010
Computer systems:
- Laptop: Laptop computer with 1 Intel Core 2 Duo L7800 dual-core CPU, 2.00 Ghz, 2.0 GB memory, Cygwin under Windows 7, g95 Fortran compiler.
- Desktop: Desktop computer with 1 Intel Core 2 Q9400 quad-core CPU, 2.66 Ghz, 4.0 GB memory, Ubuntu 8.10 Linux, Intel or gfortran (-O3) Fortran compiler.
- Server: Linux cluster system with 20 nodes, each having 2 Intel Xeon E5462 quad-core CPUs, 2.80 Ghz, 16 GB memory, Ubuntu 8.04 Linux, Intel Fortran compiler, OpenMPI.
- Mac mini: Mac mini with 1 Intel Core 2 Duo dual-core CPU, 2.53 Ghz, 4.0 GB memory, Mac OS X 10.6.2, Intel or gfortran (-O3) Fortran compiler.
Benchmark types:
- Basic: Structure calculation of a protein with 114 amino acid residues, 1737 NOE distance restraints, 110 torsion angle restraints. 50 conformers are calculated using 4000 torsion angle dynamics steps per conformer.
- Auto: Structure calculation with automated NOESY assignment of a protein with 114 amino acid residues, 4732 NOESY cross peaks, 88 torsion angle restraints. 8 x 100 = 800 conformers are calculated using 10000 torsion angle dynamics steps per conformer.
- Test suite: Complete CYANA 3.0 test suite, comprising the 'basic' and 'auto' calculations, as well as structure calculations for homodimers, structure calculations using RDCs, pseudocontact shifts, etc.