AB Genesis Simulator is a single-file conceptual simulation and benchmark environment for exploring an A/B interference possibility field, P_in actualization flow, and Pi boundary-closure operators.
The simulator visualizes how internal Pi boundary regions organize possibility-field states into stable electron-like vortices, matter-like condensates, matter-like clusters, and larger galaxy-like boundary closures.
AB Genesis Simulator is designed as a conceptual modeling, visualization, and benchmark platform for the SGEM-PM framework. It is intended for exploration, comparative parameter studies, emergence visualization, and benchmark generation.
This simulator is a conceptual toy model and research-visualization instrument. It is not an empirical proof of electron formation, matter formation, galaxy formation, or Big Bang physics.
Phan Thanh Trung Independent Researcher, Vietnam
ORCID: https://orcid.org/0009-0000-7520-6781
AB Genesis Simulator serves as a computational conceptual modeling environment for investigating emergence dynamics within the SGEM-PM framework.
The simulator supports:
- Conceptual exploration
- Emergence visualization
- Benchmark generation
- Comparative parameter studies
- Experimental scenario comparison
- Report generation
The simulator is not intended to function as an empirical physics engine. Results should be interpreted as conceptual benchmark outcomes within the SGEM-PM modeling framework.
A Gemini-generated test and review version of the project is available at:
https://gemini.google.com/share/9aa0e18390b0
This link is provided for comparison, discussion, and independent evaluation of the conceptual framework and simulator presentation.
The application opens in English by default.
Vietnamese is available through the language-selection button and can be switched at any time.
- Single-file local web application (
index.html) - Runs directly in a browser
- No backend required
- No build process required
- No account or API key required
- 2D A/B possibility-field simulator
- WebGL Genesis Chamber for 3D orbital visualization
- Real-time emergence visualization
- Interactive possibility-field manipulation
- Electron-like vortex visualization
- Matter-cluster visualization
- Galaxy-like boundary-closure visualization
- Control Matrix for parameter tuning
- Telemetry Matrix for system-state monitoring
- Quantum Event Log for emergence tracking
- Phase Timeline for convergence observation
- Unified benchmark table
- Real-time simulation metrics
- PNG snapshot export
- Markdown benchmark report export
- Experimental-result documentation
Open index.html directly in a modern web browser.
Recommended browsers:
- Google Chrome
- Microsoft Edge
- Mozilla Firefox
- Safari
WebGL should be enabled for full visualization support.
No installation, server configuration, package manager, or deployment step is required.
Choose a preset model from the Select Simulation Model menu.
Adjust values within the Control Matrix to define the desired experimental environment.
Press Run to initialize the current matrix.
Monitor:
- Possibility-field evolution
- Electron-like vortices
- Matter-like condensates
- Matter-like clusters
- Galaxy-like boundary closures
Click and drag inside the simulation canvas to introduce localized perturbations and stimulate vortex formation.
Track:
- Telemetry Matrix
- Quantum Event Log
- Phase Timeline
- Boundary Benchmark
Use:
- Export Image for PNG snapshots
- Export Report for Markdown benchmark reports
User-defined parameter configuration.
Optimized for stable electron-like vortex formation.
Optimized for matter-like condensation and cluster emergence.
Designed to investigate entropy dissipation and structural collapse.
Low-energy possibility-field environment.
High-noise interference environment.
Multiple internal Pi boundary regions operating simultaneously within the possibility field.
The benchmark table and exported reports use a unified measurement framework.
| Benchmark Parameter | Meaning |
|---|---|
| Topology Mode | Indicates whether the system operates as a single-boundary or multi-boundary co-genesis environment. |
| Psi Field States | Number of possibility-field nodes seeded within the simulation. |
| P_in Actualization Flux | Intensity of actualization flow injected into the system. |
| Pi Boundary Nodes | Number of active internal boundary-closure regions. |
| Electron-like Vortices | Stable rotating vortex structures formed from condensed possibility-field states. |
| Condensed Matter Points | Field nodes that have crossed the condensation threshold. |
| Matter-like Clusters | Persistent structural clusters formed from condensed vortex structures. |
| Galaxy-like Boundary Closures | Large-scale closure structures satisfying galaxy-like convergence criteria. |
| Accretion Cohesion Efficiency | Percentage of condensed nodes relative to the initial field density. |
| Galaxy Closure Convergence | Degree to which nodes, vortices, and clusters converge into a coherent higher-order structure. |
| Non-convergent Entropy | Entropy remaining dispersed and not incorporated into closure structures. |
| Sustained Closure Frames | Number of simulation frames during which closure conditions remain stable. |
| Thermodynamic Status | Aggregate status derived from entropy, vortices, clusters, and closure behavior. |
Select a preset model.
Press Reset to clear the previous run.
Press Run and allow the simulator to evolve.
Monitor the Quantum Event Log for:
- Electron-like emergence events
- Matter-like emergence events
- Galaxy-like closure events
Wait until the simulation reaches the desired phase.
Export a Markdown benchmark report.
Compare benchmark outputs across different presets using the same benchmark metrics.
The simulator implements the following conceptual emergence hierarchy:
A/B Interference Field
↓
P_in Actualization Flow
↓
Pi Boundary Closure
↓
Electron-like Vortex
↓
Condensed Matter Point
↓
Matter-like Cluster
↓
Galaxy-like Boundary Closure
This hierarchy represents a conceptual emergence sequence used for benchmark comparison and visualization.
AB Genesis Simulator is a conceptual modeling environment inspired by:
- Topological field dynamics
- Possibility-field representations
- Boundary-closure systems
- Skyrmion-like topological structures
The simulator should be used for:
- Conceptual exploration
- Emergence visualization
- Comparative benchmarking
- Educational demonstration
- Research communication
The simulator does not constitute empirical evidence for:
- Electron formation
- Matter formation
- Galaxy formation
- Cosmological evolution
- Big Bang physics
No claim is made that the simulated structures correspond directly to physical particles, physical matter, physical galaxies, or experimentally verified cosmological processes.
Licensed under the Apache License, Version 2.0.
You may obtain a copy of the License at:
https://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and limitations under the License.
Source code: Apache License 2.0
Research manuscript: Copyright © Phan Thanh Trung