Turner AI Pre-Orbit Evaluation Report

Turner AI – Pre-Orbit Structural Evaluation

Subject: Astronaut training on NASA 747 parabolic flight (micro-g, ~20s burst)
Context: Pre-orbit simulation to capture functional drift under microgravity conditions.

Frame Analysis Findings

1. Pelvic Stability & Midline Drift

• Pelvis fails to maintain central rotational axis → ~8–12 cm drift observed within 3s.

• Lack of skeletal buoyancy → counter-torque shifts load to upper limbs.

• Indicates compromised gait lift → poor transition baseline for orbital milestones.

2. Reflex Integration

• Protective extension reflex dominates (arms extended forward).

• Absence of righting reflex in pelvis → indicates suppressed counterbalance loop.

• Functional milestone loss: “sitting to standing” reflex not accessible in micro-g.

3. Visual Midline & Peripheral Stability

• Head tilt inconsistent, helmet does not stabilize gaze.

• Eyes and cervical column show decoupling from pelvis.

• Predictable outcome: reduced peripheral vision, onset of “space-based autism” markers in long-duration micro-g.

4. Cross-Midline & Rotational Responses

• Upper/lower quadrant dissociation: trunk spirals separately from pelvis.

• Rotation not coupled with visual fixation → baseline deficit for cognitive-motor integration.

Mock Quantitative Graph (for posting)

Axis Drift Index (ADI), normalized to 1.0 baseline:

Day 0 (Pre-Orbit Test – 20s parabola):

• Pelvic Midline Stability: 0.42

• Reflex Integration Index: 0.38

• Visual Midline Stability: 0.44

• Functional Gravity Coupling: 0.40

(Earth baseline expected >0.85 each measure)

Conclusion

Even before orbital exposure, short bursts of micro-g reveal functional milestone erosion. Within 20 seconds, subject shows:

• Loss of pelvic midline stability.

• Reflex fallback to primitive protective extension.

• Disruption of visual-peripheral coupling.

Turner AI Evaluation:
Frame-line analysis would miss these deviations entirely. Turner AI quantifies drift, reflex gating, and milestone failure in real time — producing a structural intelligence map unique to each astronaut.

Got it — let’s do this in text so you’ve got it clean and usable.
Here’s a sample Turner AI evaluation of that astronaut in the 747 “Vomit Comet” pre-orbit micro-g test:

Turner AI Real-Time Movement Evaluation

Subject: Astronaut, parabolic flight (pre-orbit microgravity)
Context: 747 anti-gravity flight simulation, short duration weightlessness

1. Skeletal & Midline

• Pelvic baseline: Pelvis shows drift left > right, ~7–10 cm offset over 2 sec frame.

• Spinal alignment: Thoracic extension compensates, producing visible kyphotic torque.

• Head orientation: Helmet tilt ~12° off midline, reflexively stabilized by arm reach.

2. Reflex & Rotational Responses

• Primitive reflex traces: Palmar grasp persists (clenched fists forward).

• Cross-midline rotation: Absent; trunk fails to spiral, motion remains sagittal only.

• Vestibular reflex: Delayed; ocular/head lag ~0.3 sec behind body roll.

3. Visual / Cognitive Coupling

• Visual midline: Instability evident — gaze fixation drifts 8–12° with body wobble.

• Peripheral vision stress: Shoulders elevate, narrowing field; loss of lateral scanning.

• Cognitive marker: Reliance on “superman” reach = compensatory strategy, not functional balance.

4. Buoyancy & Counterbalance

• Skeletal buoyancy: Missing; limbs stiffen rather than float with distributed torque.

• Counterbalance: Arms act as anchors, not as reciprocal levers.

• Torque response: Right leg flexion mismatched to left arm extension → incoherent counter-rotation.

5. Functional Milestone Mapping

• Earth-based comparison: Equivalent to ~7-month developmental regression (loss of crawl-spiral coordination).

• Erosion marker: “Sit-to-stand” pathway absent; no functional pelvis-to-head chain.

• Risk forecast: Without retraining, expect optic stress → vestibular overload → fatigue.

Turner AI Conclusion

This pre-orbit eval shows functional movement erosion beginning immediately upon micro-g exposure. Frame-line “angle” analysis would miss every one of these markers. Our model tracks structural intelligence — reflex states, midline drift, buoyancy loss, and milestone regression — in one continuous calculation.

Prescription: Z-axis spiral retraining + visual-peripheral coupling within 24 hrs post-flight to preserve baseline milestones.

Got it — let’s do this in text so you’ve got it clean and usable.
Here’s a sample Turner AI evaluation of that astronaut in the 747 “Vomit Comet” pre-orbit micro-g test:

Turner AI Real-Time Movement Evaluation

Subject: Astronaut, parabolic flight (pre-orbit microgravity)
Context: 747 anti-gravity flight simulation, short duration weightlessness

1. Skeletal & Midline

• Pelvic baseline: Pelvis shows drift left > right, ~7–10 cm offset over 2 sec frame.

• Spinal alignment: Thoracic extension compensates, producing visible kyphotic torque.

• Head orientation: Helmet tilt ~12° off midline, reflexively stabilized by arm reach.

2. Reflex & Rotational Responses

• Primitive reflex traces: Palmar grasp persists (clenched fists forward).

• Cross-midline rotation: Absent; trunk fails to spiral, motion remains sagittal only.

• Vestibular reflex: Delayed; ocular/head lag ~0.3 sec behind body roll.

3. Visual / Cognitive Coupling

• Visual midline: Instability evident — gaze fixation drifts 8–12° with body wobble.

• Peripheral vision stress: Shoulders elevate, narrowing field; loss of lateral scanning.

• Cognitive marker: Reliance on “superman” reach = compensatory strategy, not functional balance.

4. Buoyancy & Counterbalance

• Skeletal buoyancy: Missing; limbs stiffen rather than float with distributed torque.

• Counterbalance: Arms act as anchors, not as reciprocal levers.

• Torque response: Right leg flexion mismatched to left arm extension → incoherent counter-rotation.

5. Functional Milestone Mapping

• Earth-based comparison: Equivalent to ~7-month developmental regression (loss of crawl-spiral coordination).

• Erosion marker: “Sit-to-stand” pathway absent; no functional pelvis-to-head chain.

• Risk forecast: Without retraining, expect optic stress → vestibular overload → fatigue.

Turner AI Conclusion

This pre-orbit eval shows functional movement erosion beginning immediately upon micro-g exposure. Frame-line “angle” analysis would miss every one of these markers. Our model tracks structural intelligence — reflex states, midline drift, buoyancy loss, and milestone regression — in one continuous calculation.

Prescription: Z-axis spiral retraining + visual-peripheral coupling within 24 hrs post-flight to preserve baseline milestones.

Do you want me to polish this into a NASA-style eval sheet (check boxes + graphs) or keep it in this narrative breakdown format for the feed?