Jael Todorov: Difference between revisions

Jael, a lifelong outcast, learns to use the full power if her exclusion from mainstream society as a way to liberate others.

• Character's goal: Jael wants to prevent the megacorporation from gaining control of the virus and using it as a means to further oppress society.
• Character's motivation: Jael wants to escape the social hierarchy she is trapped within.
• Character's conflict: Jael is often in conflict with Darius over their respective reasons for challenging the megacorporations.
• Character's epiphany: Jael, once she has full control of her Spryt, realizes she has more power than society has told her.

A one-paragraph summary of the character’s storyline

Biography

Early life

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Professional life

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Relationships

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Characteristics

Physical Appearance

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Personality

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Health

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Augmentations

Cynernetics

Because she grew up in one of the earliest Unseen settlements, Jael recieved her Spryt later than the average citizen. After leaving the settlement and making her own way to Chongquing, Jael had her Spryt installed when she was 15. Jael's Spryt is called Spryt because no one told her she could give it a unique name. They have a detached and professional relationship. Unlike most people who consider their Spryts as a companion if not a friend, Jael sees her Spryt simply as another tool. Despite this, she is quite adept at using her Spryt, far exceeding the effectiveness of most Human-Spryt relationships.

Bionics

Left eye

Six years ago, Jael had her left eye replaced with an Argus Tactical Model VI, a lab grown eye that provides her with multiple types of visual enhancements:

• Multi-Spectral Vision
  • Infrared/Ultraviolet Imaging detects heat signatures (for night vision, tracking targets in darkness) and ultraviolet patterns (e.g., forensic evidence, hidden security markings).
  • Polarized Light Detection identifies material stress (cracks in structures) or camouflaged objects by analyzing light polarization.
• AI-Powered Scene Analysis
  • Real-Time Threat Detection uses deep learning to flag weapons, hostile movements, or environmental hazards (e.g., unstable terrain).
  • Enhanced Biometric Scanning recognizes individuals via gait analysis, thermal signatures, or retinal patterns, even in crowds.
• Enhanced Ranges and Sensors
  • Adjustable Zoom (3x–30x) enables long-range surveillance or microscopic inspection.
  • Low-Light Optimization functions in 0.001 lux (starlight-level darkness) with minimal noise.
  • High-Speed Tracking processes motion at 1,000 fps (vs. human 60 fps), critical for intercepting fast-moving threats.
  • LIDAR Mapping generates 3D depth maps for precision navigation in complex environments.
  • EM Spectrum Detection identifies active electronics, wireless signals, or power sources via electromagnetic emissions.
• Lab-Grown Biological Improvements
  • Lab-grown Retinal Tissue repairs minor damage, reducing rejection risks and maintaining optical clarity.
  • Bioengineered Photoreceptors interface seamlessly with cybernetic sensors, minimizing latency (≈1 ms delay).

Left Arm

Twenty years ago, Jael had her left arm removed at the shoulder and replaced with an Airgetlám Mark II prostehtetic arm. Four years ago, she upgraded to the Airgetlám Mark X. This bionic arm gives her the following capabikities:

• Superhuman Load Capacity
  • Advanced actuators and carbon-fiber tendons enable lifting up to 50 kg with a single-arm grip.
  • Piezoelectric systems amplify force output, allowing bursts of power for tasks like crushing objects or breaking barriers.
• Self-Healing Materials
  • Smart polymers in the arm’s frame repair minor cracks or wear autonomously, ensuring durability during high-stress scenarios.
• Multi-Axis Wrist and Finger Control
  • A 10-degree-of-freedom system replicates natural wrist rotation (0–180°), thumb opposition, and individual finger articulation, enabling fluid transitions between grips (e.g., precision pinch to power fist).
  • AI-driven predictive movement (via Spryt integration) anticipates tasks, adjusting grip patterns or joint angles milliseconds before action.
• Neuromuscular Synergy
  • Osseointegrated titanium implants fuse the arm to her skeleton, while implanted electrodes in residual nerves enable sub-100ms response times-faster than biological reflexes.
• Tactile Sensory Feedback
  • Artificial skin with micron-scale pressure sensors detects textures, temperatures, and forces as low as 0.1 Newtons, allowing her to handle fragile objects or perform microsurgery.
  • Direct neural feedback simulates proprioception, granting subconscious awareness of the arm’s position in 3D space.
• AI-Enhanced Targeting
  • Machine learning algorithms refine grip stability and trajectory accuracy over time, achieving ±0.05mm precision in repetitive tasks (e.g., lock-picking, circuitry repair).

The upgraded arms also enables better integration with other augmentations.

• Spryt
  • The arm’s onboard AI cross-references Spryt’s environmental data (e.g., object weight, surface friction) to optimize grip force and motion paths in real time.
  • The Spryt’s retinal HUD projects real-time force metrics (e.g., grip strength, object weight) or hazard alerts (e.g., “Overload risk: 85%”), synchronized with the arm’s sensory data.
• Smart Jack Relay
  • Adrenaline surges from her nanoparticle implant temporarily override safety limits, unlocking 120% peak performance during combat or emergencies.
• Argus Tactical Model VI
  • Visual-Tactile Feedback Loop
    • The bionic eye’s multi-spectral imaging could inform the arm’s tactile sensors to adjust grip force or surface interaction in real time.
  • Predictive Targeting
    • The bionic eye’s AI threat detection (e.g., tracking hostile movements at 1,000 fps) could preemptively signal the arm to position itself defensively or prepare a specific grip (e.g., drawing a weapon).
  • Micro-Adjustments via Visual Data
    • The eye’s telescopic zoom could feed spatial data to the arm’s AI, enabling micron-level precision for tasks like disarming explosives or repairing circuitry.
  • Shared Neural Pathways
    • Both systems interface with Spryt, which acts as a central processor. For example:
      • Visual input from the left eye detects a target → Spryt calculates trajectory → Arm executes the motion with <0.1ms latency.
      • The eye overlays dynamic reticles on threats, while the arm’s gyroscopic stabilizers auto-align for precision strikes.
    • Cross-Modal Learning
      • The Spryt could use reinforcement learning to correlate visual patterns (e.g., a crumbling ledge) with optimal arm behaviors (e.g., “grip force: 12N”), improving performance over time.

Genetic engineering

(CRISPR-based modifications)

Pharmacological enhancements

Jael's first optional augmentation was a Strong Jack Relay, a nanopartical magnetic remote system. On command from her Spryt, a magnet implanted on her fifth rib heats up nanoparticals in her adrenal gland which cause the release of adrenaline, noradrenaline, and cortisol -- either individually or in combination -- by targeting specific regions of the gland with tailored magnetic fields.

• Adrenaline triggers the fight-or-flight response, rapidly increasing heart rate, blood flow to muscles, energy release (glucose), and overall alertness, which is essential for immediate physical reactions and peak muscular action.
• Noradrenaline works with adrenaline to increase alertness, blood pressure, and readiness for action, enhancing focus and reaction time during high-stress situations.
• Cortisol mobilizes energy by increasing glucose in the bloodstream, regulates metabolism, and helps manage stress. While excessive cortisol can impair performance, controlled surges can be beneficial for energy mobilization in acute stress.

Plot Synopsis

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