Project Plans

This page lists projects that are currently in development or planned for future development.

Andorville™ Multi-Cellular Software Development System
The Andorville™ multi-cellular software development system is used to quickly build large and complex software applications.
The multi-cellular architecture limits the system complexity as the size of an application increases.

Features of the system include:

Software Cells - The system contains a variety of software cells. Each cell provides a single function within the application
Projects - Projects contain information used by an associated software cell while it is running
Project Tree - Complex data models are constructed by assembling a project tree
Network - The Andorville™ Network connects all software cells in an application and allows messages to be exchanged between cells

New software cells can be created from a template when an application needs a new function.
The template contains the following functions required to operate in a multi-cellular environment:

Project Connection - Connects the software cell to the associated project, which contains data model information and instructions
Network Connection - Connects the software cell to the Andorville™ Network, allowing messages to be exchanged with other cells in the application
Message Processor - Used to execute messages received from other software cells
Workflow Management - Manages workflows designed by a user - Workflows are HTML documents that provide tailor-made user interfaces or information displays
- JavaScript functions can be included in the workflows to control the software cell

Andorville™ Distributions Application
The Distributions application is used to design, analyse and simulate data from a variety of continuous and discrete probability distributions.

A set of workflow pages is being designed to demonstrate the software and show how probability distributions are used to model random processes.

Andorville™ Q7 Application
The Q7 application is designed to investigate the Andorville™ frequency domain interpretation of Quantum Mechanics.

The Andorville™ 3DF-0DT quantum physics model has three frequency dimensions and no time dimension.
A time dimension is not required because quantum mechanics is modelled as a three dimensional frequency domain, in-place computational system.

Frequency domain physics explains many observations:

the universal laws of physics - frequency domain operations are invariant in the corresponding space domain
distance in the apparent space domain - corresponds to phase differences in the frequency domain
the double slit experiment - energy of a particle evolves in the frequency domain and is only localised by an interaction (an observation)
the apparent collapse of the wave function - localisation caused by an interaction

The zero time dimension (in-place computational system) explains:

the conservation laws
why light must be quantised

In the 3DF-0DT model, particles only exist in the apparent space domain at the moment of interaction, which is also called an observation.
For example, when the energy of a photon interacts with the energy of an electron, they are localised a point in the apparent space domain.
The localisation is analogous to an inverse Fourier transform.
Between interactions, the energy of electrons and photons evolves in the frequency domain.

Andorville™ Self-Aware Autonomous System
The Andorville™ self-aware autonomous system (AnSAAS) is a software system for controlling a defined hardware system within a surrounding environment.

AnSAAS contains models of the hardware and the environment.
The models are constructed using an Andorville™ project tree and associated software cells.
The hardware behaviour is simulated using a range of settings over different time scales.
The time dimension required for a simulation is created using memory.
The time dimension also allows simple trend forecasting to be used in a simulation.

Settings are optimised by comparing performance measures based on the simulation results.
The models are also refined by comparing predicted simulation data with measured data.

The term "self-aware" refers to the model of the defined hardware system and the simulated behavour of the system in time, which is used to compare and select the optimum behavour.

AnSAAS may be used as a simple model for animal self awareness.
The sense of time is a perceptual artifact of the brain that allows us to plan and optimise behaviour.

Ani Image Ani - Technical Assistant
The Ani technical assistant is a self-aware storage and retrieval system for science and technology information.

Ani is designed to provide technical advice in a range of problem domains.
Problem domain expertise is coded using Andorville™ project trees.

Image used under license from Shutterstock.com