Consultancy

Progress against our strategic goals

NeSI delivers specialist computational science expertise to the research sector, embedding NeSI’s team members within research teams during the course of a project. NeSI experts come from a variety of science domain backgrounds, have extensive programming experience, and can assist with code optimisation, parallelisation, custom code development, and many other tasks. Through these collaborations, NeSI lifts researchers’ productivity, efficiency and skills using research computing tools and resources.

Strengthening our specialist science capabilities

During 2018, NeSI focused on broadening uptake of its Consultancy service by a wider range of organisations and improving visibility of the work undertaken by the NeSI Consultancy team. The efforts paid off, with 2018 being the first year that NeSI succeeded in identifying and working alongside research groups from all Collaborators (University of Auckland, NIWA, University of Otago, and Manaaki Whenua – Landcare Research) and the first time NeSI worked with AgResearch on a Consultancy project.

The Consultancy team also looked closely at how the service is promoted, with the goal of ensuring all NeSI researchers are aware of the Consultancy service and how to access it. Existing processes were optimised and new tactics were put in place, including presenting talks at various conferences, advertising the service within the compute allocations process, and adding information about Consultancy to the platform’s login interface.

With the growing opportunities for researchers in data science, NeSI wanted to build its internal expertise in this area. Unfortunately, we were unable to identify a suitable candidate for a data science role in our team, but recruitment is likely to continue in 2019.

Consultancy projects in 2018

Project nameContributions and benefits realisedScience outcomesPrincipal investigator
Global Climate ChangeThis project enabled the use of the second global climate model that will have been run and tested in New Zealand. The results from this project can be compared with those obtained from the HadGEM model currently used by NIWA.

Without this consultancy project the researcher would not have been able to carry out this research on NeSI.
Understanding the relationships between atmospheric CO2, water vapour, clouds, and global circulation for better prediction of climate change.

Investigating how changes in CO2 level is linked to changes in atmospheric humidity and clouds, which feedback on the radiative energy budget of the Earth’s climate system, and in turn affecting climate sensitivity.
Tra Dinh University of Auckland, Department of Physics
Optimisation of tracking algorithm for precipitation systemsCode is now able to run on the new platforms.

Without these changes the researcher will not be able to run the full analysis and therefore will not be able to publish results from this work.

The researcher was also upskilled in version control and software engineering practices.

Performance gains of 3.5 - 5.5x were realised against the initial working version.
Tracking coastal precipitation systems in the tropics.

Coastal precipitation plays an important role in the economy of island nations. Impacts from too much or too little precipitation can range from losses in agricultural productivity, to unexpected infrastructure costs, to spikes in sales of particular products or services.
David Coppin
University of Auckland, Department of Physics
NZESM Model DevelopmentNIWA NeSI team member helped migrate the climate model to the new platforms.

Accelerated the set-up of the New Zealand Earth System Model (NZESM) on the new platforms; improved efficiency; reduced core-hour usage; ensured downstream users get data as quickly as possible.

10.3 million core hours usage on the new platforms in 2018.
Producing useful climate simulations using a hierarchy of models.

The NZESM is at the core of the Deep South Challenge, a large-scale science challenge project that investigates climate change and its consequences for New Zealand.
Olaf Morgenstern
NIWA,
Deep South Challenge
Code Optimisation for Genotyping-By-SequencingResearchers learnt how to optimise and parallelise R codes and have already applied this to other codes they are working on.

Performance improvements of up to 20x speed up.
Incorporating new computational methods and tools into analysis of genetic relatedness and construction of genetic linkage maps.Jeanne Jacobs
AgResearch
Porting Community Earth System Model (CESM) to NeSI​Assisted in code porting, so that the researcher could use NeSI. This involved comparing available compilers and choosing the best performing one.

CESM is a community code, so having it available on the NeSI platforms should be useful for other researchers going forward.
Exploring how changes in the sun, particularly an effect known as energetic particle precipitation or “solar wind”, influences things like ozone balance in the polar atmosphere and how that impacts other climate elements.Annika Seppälä
University of Otago, 
Department of Physics
Modelling discretized point processes with extra zeros and long-range dependenceConsultancy enabled better throughput and efficiency on the NeSI platforms and support for more complex models and larger datasets. Performance improvements of ~3x speed up overall.

This project enabled the development of more advanced models for earthquake modelling.

Code has also been shared with the broader scientific community.
Modelling the first of its kind in the type of seismic events analysis. Will help forecast large destructive earthquakes.Ting Wang
University of Otago, 
Department of Maths 
and Statistics
GRATE Sediment Transport CalculatorThis project is underway but it is expected that it will increase the usability of the code, and make it suitable for running on NeSI platforms.

We are also aiming to improve performance of the code.
GRATE is a research tool that can be applied to numerous practical problems in NZ rivers. It will be an effective educational tool, as well as a valued resource for assessing field data.Jon Tunnicliffe
University of Auckland, 
School of Environment
Generation of 
sub-Poissonian radiation fields 
of large photon 
number
Introduced research software engineering best practices by implementing a new build system, test cases and improving the accuracy of the calculations.

Improved the performance of individual simulations, saving 39% of run time.

Implemented scripts for automating parameter sweeps involving running large numbers of simulations in parallel, which will save time compared to manually running those simulations.
This code will be applied to simulations of open quantum systems, in particular simulating the fundamental interaction of light and matter.Howard Carmichael
University of Auckland 
Department of Physics
Monitoring land cover changes with TMASK_SENTINELThe code was parallelised, resulting in a 53x speedup over the original, serial version.

The master - worker approach implemented here can be used as a framework to parallelise other similar codes (upskilling the researcher).
The code is intended to play an important role in monitoring land use in New Zealand and overseas.James Shepherd
Manaaki Whenua - Landcare Research
Conservative Interpolation for Forecasting Weather HazardsA method for conservative interpolation was developed during this consultancy project, enabling the remapping (regridding) of vector fields from and to arbitrary unstructured grids made of quadrilateral cells. Achieve conservation of water and energy when regridding vector fields between different grids, e.g. from the cubed-sphere grid used by the weather/climate LFRic code to a longitude-latitude grid. Can be used to compute the amount of water flux and energy entering a region over time to much higher accuracy than was previously the case. Michael Uddstrom
NIWA

 

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