Founded and chaired the organisational team for Melbourne's inaugural ServerlessDays event. As well as leading the team, I personally worked with sponsorship and promotional activities.

Having joined HeadUp Labs as developer number 4, I was later promoted to engineering manager. As manager, I grew the team to 7, emphasises quality, and instituted a bottom-up planning process.

I lead a multi-discipline team responsible for integrating systems and automating processes for an international, vertically integrated organisation. Reporting to the CTO, I routinely advised the CEO and CFO directly and was regularly required to provide technical context to inform strategic decision making.

I enjoy using my broad base of technical skills to ensure a high return on investment is realised through our fundraising activities. During my time in this position I have successfully made the case for investment, growing the team to include two Data Processing executives and a Business Intelligence officer.

Together, we deliver intelligence and analysis using the MS SQL stack (inc. SSRS), extend our in-house tooling using visual basic, and develop new applications primarily in C#.

Administering the MS SQL based CRM database, ensuring the data was of high quality, and instilling best practice in its use. I was also responsible for delivering analysis and for enabling colleagues to do the same.

Radio Free Brighton is a community radio station based in Brighton on the south coast of England. As technical director (a voluntary role) I oversaw operations in the studio and online. This included administering the servers, building and maintaining the website, and developing applications that helped the station to run.

I originally volunteered to take on the promotion of the launch event, which took place at the beginning of September, but ended up staying on to develop a long term social media strategy.

Binary Star Digital was the formalisation of the part-time web development that funded my time at university. I partnered with a creative colleague and together we worked for a wide range of clients to deliver websites and facebook applications. Notable clients included IDEO (international design firm) and the International Planned Parenthood Federation.

Completed courses:

• C# Tips and Traps 2
• C# Tips and Traps
• More Effective LINQ
• Microsoft Azure Service Bus Brokered * Messaging In-depth
• F# Jumpstart
• OWASP Top 10 Web Application Security Risks for ASP.NET

As well as completing my PhD, I am fortunate enough to have had a couple of papers published in scientific journals. For example:

• The evolution of a visual-to-auditory sensory substitution device using interactive genetic algorithms
• Sensory substitution as an artificially acquired synaesthesia

I have also enjoyed the opportunity to teach both undergraduates and my postgraduate peers. I have:

• Taught on a 1st year course called "Psychobiology", where we discussed topics such as models of learning, addiction and evolutionary psychology.
• Developed and delivered a series of training events for other tutors whilst I held the role of "associate tutor rep".
• Convened, designed and delivered a course called "Matlab for experimental psychologists", which will likely run again in 2013/14.

I graduated from Sussex in 2009 with a 1st Class Honours degree in Cognitive Neuroscience.

This course was perfect for me, as it combined the biology of the brain with psychology and computer science.

During my time at Sussex I was also heavily involved with the digital aspects of student media. In 2008 I was awarded the "Innovation of the year" award for an event calendar project. In 2009 I was honoured to receive an award recognising my "Overall contribution to student media".

Simple yet flexible tables for console apps.

Ployglot Framework for Sensory Substitution Devices

Sole developer - this project formed the foundation of my PhD thesis.

Android app which makes devices into haptic touchpads

NAudio (C#) class for generating localised tones

Round Robin Queue for .NET

Provides the necessary elements to create an HSV colour picker in C#

Sensory substitution devices convert information normally associated with one sense into another sense (e.g. converting vision into sound). This is often done to compensate for an impaired sense. The present research uses a multimodal approach in which both natural vision and sound-from-vision (‘soundscapes’) are simultaneously presented. Although there is a systematic correspondence between what is seen and what is heard, we introduce a local discrepancy between the signals (the presence of a target object that is heard but not seen) that the participant is required to locate. In addition to behavioural responses, the participants’ gaze is monitored with eye-tracking. Although the target object is only presented in the auditory channel, behavioural performance is enhanced when visual information relating to the non-target background is presented. In this instance, vision may be used to generate predictions about the soundscape that enhances the ability to detect the hidden auditory object. The eye-tracking data reveal that participants look for longer in the quadrant containing the auditory target even when they subsequently judge it to be located elsewhere. As such, eye movements generated by soundscapes reveal the knowledge of the target location that does not necessarily correspond to the actual judgment made. The results provide a proof of principle that multimodal sensory substitution may be of benefit to visually impaired people with some residual vision and, in normally sighted participants, for guiding search within complex scenes.

In this review we explore the relationship between synaesthesia and sensory substitution and argue that sensory substitution does indeed show properties of synaesthesia. Both are associated with atypical perceptual experiences elicited by the processing of a qualitatively different stimulus to that which normally gives rise to that experience. In the most common forms of sensory substitution, perceptual processing of an auditory or tactile signal (which has been converted from a visual signal) is experienced as visual-like in addition to retaining auditory/tactile characteristics. We consider different lines of evidence that support, to varying degrees, the assumption that sensory substitution is associated with visual-like experiences. We then go on to analyse the key similarities and differences between sensory substitution and synaesthesia. Lastly, we propose two testable predictions: firstly that, in an expert user of a sensory substitution device, the substituting modality should not be lost. Secondly that stimulation within the substituting modality, but by means other than a sensory substitution device, should still produce sensation in the normally substituted modality.

Sensory substitution is a promising technique for mitigating the loss of a sensory modality. Sensory substitution devices (SSDs) work by converting information from the impaired sense (e.g., vision) into another, intact sense (e.g., audition). However, there are a potentially infinite number of ways of converting images into sounds, and it is important that the conversion takes into account the limits of human perception and other user-related factors (e.g., whether the sounds are pleasant to listen to). The device explored here is termed “polyglot” because it generates a very large set of solutions. Specifically, we adapt a procedure that has been in widespread use in the design of technology but has rarely been used as a tool to explore perception—namely, interactive genetic algorithms. In this procedure, a very large range of potential sensory substitution devices can be explored by creating a set of “genes” with different allelic variants (e.g., different ways of translating luminance into loudness). The most successful devices are then “bred” together, and we statistically explore the characteristics of the selected-for traits after multiple generations. The aim of the present study is to produce design guidelines for a better SSD. In three experiments, we vary the way that the fitness of the device is computed: by asking the user to rate the auditory aesthetics of different devices (Experiment 1), and by measuring the ability of participants to match sounds to images (Experiment 2) and the ability to perceptually discriminate between two sounds derived from similar images (Experiment 3). In each case, the traits selected for by the genetic algorithm represent the ideal SSD for that task. Taken together, these traits can guide the design of a better SSD.