The Mark 3 Vertex Integrated Scanner can be either folded and an unfolded. In the folded mode, the Mark 3 Vertex Integrated Scanner resembles a sleek and compact data access device, with a 14.7-cm Quantum Dot LED (QLED) display, a triple camera system, and a fingerprint sensor. The folded mode allows the user to perform basic functions, such as scanning for aether signatures, communicating with other devices, and accessing the Solas Tempus database. In the unfolded mode, the Mark 3 Vertex Integrated Scanner transforms into a 19.3-cm tablet, with a flexible and durable screen that can bend without breaking.
Holographic Interface
The device has a built-in holographic display system that can produce 3D images that can interact with the user and the environment. The holographic display system uses the Quantum Dot LED (QLED) display as a source of light and energy, and projects holographic energy in specific patterns effectively around the device.
The holographic display system has two modes, a high quality mode and a low quality mode. In the high quality mode, the holographic display system can create high resolution and high quality holograms that can extend up to 10 meters from the device. The holograms in this mode can be touched and manipulated by the user, and can also respond to the physical and temporal properties of the environment. In the low quality mode, the holographic display system can create low resolution and low quality holograms that can extend up to 40 meters from the device. The holograms in this mode have no surface to touch, and are mainly used for visual and auditory communication and information. The low quality mode is useful for long range scanning and detection of anomalous signatures, as well as for emergency and distress signals and messages.
The holographic display system can be controlled and customized by the user, using voice commands, gestures, or the device interface. The user can adjust the size, shape, color, brightness, and volume of the holograms, as well as the angle, distance, and direction of the projection. The user can also switch between the high quality and low quality modes, depending on the situation and the purpose of the holograms.
Capabilities
This device is a powerful and versatile scanning and data processing system that can operate in any environment and situation. It can use a range of sensors to detect and measure various aspects of the surrounding area, such as subspace, electromagnetic, temporal, infrared, visible light, ultraviolet, audio, biomedical, and genetic properties. It can also handle and coordinate multiple dynamic data streams simultaneously from remote sensing, library computer access, and internal sensing systems, using high bandwidth isolinear and optical data processing suite and bioneural circuitry with RNA sequence memory storage. Moreover, it can remotely control and coordinate other devices and systems, such as piloting vehicles, commanding surveillance drone swarms, and managing active repair systems. Not all features are available in all scenarios, some features such as temporal scanning and similar are subject to security clearances provided by Solas Tempus.
Scanning
- VAM Enhanced Sensor Pallet
- Active & Passive Ultra High Resolution Subspace & Scanners
- Quantum Resolution Directed Active & Passive Scanner Elements
- These are designed for close (within a meter or less) in depth scans of objects.
- Active & Passive Temporal Scanner
- Real-Time Audio, EM, and Subspace Pattern Analyzer
- Active & Passive Audio Imaging System
- Can generate live sonar and echo-location data into an accurate 3D representation.
- Active & Passive Atomic Resolution Biomedical Scanner w/ RNA & DNA Sequence Analysis
Data Processing
- High Bandwidth Isolinear & Optical Data Processing Suite with NLQPA Core
- Bioneural Circuitry with RNA Sequence Memory Storage
- Remote Command and Control Interface
- Multinodal Core
- The device can be activated as it's own multinodal core rather than having one inserted.
Range
Range
The range of the device is dependent on many factors. Under standard conditions, the scanning elements have these ranges. Closer is always preferred, as the closer the object is, the more processing systems and additional sensor data can be added to assist in analysis. Communication with a larger computer system or multiple Vertex devices can also aid in increasing resolution.
| Type | Range | Description |
|---|---|---|
| Planck Scale Analyzer | 2.1 meters | Quantum resolution scanner, used to create an accurate multi-dimensional image down to the quantum level. Detects sub-atomic particle composition and configuration with Heisenberg decomposition analysis to provide high resolution approximations of unstable quantum fluctuations. |
| Molecular Resonance Scanner | 27.9 meters | Molecular resolution scanner, can accurately make a detail map down to the atomic scale including atomic. This includes detailed molecular composition imaging with accurate isotope differentiation. |
| Geological Sensor Array | 13.2 km | Specifically designed for detailed surface scans of planets and stellar bodies during away missions. |
| VAM Topographical Imaging Array | 28.4 km | Specialized for studying various subspace energy flows not otherwise scanned for, ties in with all other sensors to assist in data processing. |
| Neutrino Emission Scanner | 23.65 km | Focused neutrino detection and imaging scanner specialized for short-range detection. |
| High Resolution Temporal Scanners | 161 km | Specialized sensors offering high-resolution detection of temporal anomalies. These scanners can be tied to the Planetary Sensor Array for higher resolution scans of smaller anomalies. |
| Short Range Sensors | 305.6 km | General purpose high resolution sensors with both active and passive elements. These sensors are also equipped with a general purpose imaging systems which assist other sensor clusters in generating higher resolution data within the short range sensor range. |
| Subspace Distortion Sensors | 899 km | Geared towards detecting major subspace distortions. |
| Advanced Spectral Analyzers | 1211 km | Specialized sensors capable of analyzing detailed spectral data. |
| Low Resolution Temporal Anomaly Sensors | 1608 km | Designed to detect temporal anomalies at a lower resolution. |
| Gravitational Displacement Scanners | 1722 km | Focused on detecting large fluctuations in gravitational fields. |
| Long Range Sensors | 2081 km | Optimized for detecting larger / high mass objects at low resolution or large field fluctuations with similar fidelity. |
Components
- QLED Holographic Displays
- A pair of displays, the primary display is a 14.7 cm holographic Quantum LED (QLED) display. The secondary display is a 19.3 cm holographic QLED as well but is also designed to fold and unfold without breaking.
- Multiphasic Sensor Suite
- An advanced multiphasic sensor suite based on the VAM Enhanced Sensor Pallet that can capture high-quality images and videos in various modes and environments.
- Multi-Factor Biometric Security
- A security system that can compare detailed sensor readings of the operator with the person it is assigned to, using fingerprint, iris, voice, and DNA recognition.
- NLQPA
- A Non-Linear Quantum Processing Array (NLQPA) that can handle complex non-linear algorithms, encrypt and decrypt data, and resist temporal interference.
- MAFS
- A Multiphasic Anomaly Field Scanner (MAFS) that can detect, measure, and analyze, patterns by processing the incoming sensor data through it's anomaly detection and analysis software.
History
The MAFS was first conceived in 2385, when Solas Tempus realized that there was a need for a smaller and more portable scanning device that could operate in different situations and locations. The existing vertex scanners were bulky and limited in functionality, and the vertex combat scanners were too specialized and expensive. Solas Tempus needed a more efficient and versatile device that could serve multiple purposes and users. Solas Tempus assigned a team of engineers, scientists, and aether experts to work on the project, codenamed Nova Horizon. The team was inspired by a foldable data access device that was released in 2384 and became the standard for Solas Tempus agents and allies. The team decided to use the foldable data access device as a base model and modify it with aether technology and Solas Tempus specifications.
The team faced many challenges and setbacks during the development process, such as finding a suitable material for the foldable screen, integrating the NLQPA and the MAFS, and optimizing the battery life and performance. The team also had to deal with the constant threat of temporal attacks and sabotage from hostile factions that wanted to exploit or destroy the device. The team finally completed the prototype of the MAFS in 2389, after four years of hard work and dedication. The prototype was tested and approved by Solas Tempus, and the device was ready for mass production and distribution. The MAFS was hailed as a breakthrough in aether technology and a vital tool for temporal defense.