In an era where ecological regeneration is no longer optional but essential, BioVolt Aero (working title) introduces a breakthrough in autonomous environmental care. Leveraging hydrogen fuel cell technology (beginning models would be battery), precision AI, and biomimicry-inspired design, our drones do more than fly — they heal. They map remote ecosystems with GPS precision, identify botanical species in real time, and deliver targeted applications of organic fertilizers, all while emitting zero carbon. Every flight is a step toward revitalizing degraded lands, empowering permaculture systems, and rewilding the planet autonomously. We use long known all nature indegioenous taught compisitions, as well as super-powered, new, Nutritional Diversity optimal versions of organic applications/preperations.

Designed for the frontlines of ecological transformation, BioVolt Aero operates without compromise. With an integrated docking and refueling system, our drone technology forms a closed-loop solution capable of operating in the most remote, rugged, and biodiverse environments on Earth. Whether it’s jungle permaculture in Panama, high-altitude plots in Colombia, or experimental food forests worldwide, BioVolt Aero provides precision care with minimal human input. This is not just agricultural tech — it’s regenerative intelligence in motion.

BioVoltair is the self-charging, GPS-precise field drone built to grow abundance where tractors can’t. Each unit launches from a solar “nest,” flies RTK waypoint routes with 2–3 cm accuracy, and hot-swaps payload pods for foliar feeding, dry solids dropping (seed-balls, biochar, inoculants), or selective harvesting. The result is continuous, surgical care—night or day, in steep, wet, or sensitive terrain—without soil compaction, road cuts, or wasted inputs. Think variable-rate teas on stressed zones at dawn, seed-ball corridors by afternoon, and crown-level harvests at dusk—all from the same autonomous fleet.

For operators, that precision translates into outcomes: 20–40% input savings, 5–15% yield lift in season, and brand-new resource streams from rapid interplanting and reforestation—fruit, leaves, resins, timber, carbon. A 10-drone swarm can treat 100+ hectares per day, place tons of beneficial solids monthly, and document every drop and seed with GPS time-stamps for organic/regenerative audits. If you’re ready to scale regenerative production with lower costs, higher biodiversity, and real-time proof of impact, equip your land with BioVoltair and start growing ecosystems like software.

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Executive Summary: BioVolt Aero is a regenerative technology company pioneering the use of hydrogen-powered, AI-assisted autonomous drones for ecological restoration and enhancement, organic agriculture, and precision botanical care. Our drones identify, monitor, and nurture plant life through GPS-guided missions, delivering micro-dose organic fertilizers and operating on a closed-loop hydrogen refueling system. Designed to serve remote landscapes and degraded ecosystems, BioVolt Aero offers an emission-free, intelligent alternative to conventional land management systems.

Mission Statement: To accelerate the planet’s ecological recovery and enhancement throughintelligent, autonomous technologies that care for nature with zero emissions and maximum precision and effect.

Problem Statement:

• Remote environments are difficult and costly to manage or enhance
• Traditional agricultural methods are carbon-intensive and imprecise, and outright toxic to everything and everyone
• Regenerative agriculture and permaculture lack scalable tools for monitoring and micro-treatment
• Current drone technology lacks full autonomy, organic compatibility, and sustainable energy systems behind a system made from nature, natural practice, and life.
• In our last 15 years of jungle study, we have realized a whole level of potential in the human-to-nature relationship, and we see this as a vehicle to catch us up to where we should have been truly!

Solution: BioVolt Aero combines hydrogen fuel cell technology with AI-powered plant recognition, creating a drone system capable of:

• Autonomous flight using RTK GPS and obstacle detection
• Real-time plant ID and health analysis via onboard camera and AI
• Precision spraying of organic fertilizers
• Autonomous return and docking at hydrogen and nutrient refueling stations

Product Features:

Model I

This will be the first development of a consumer product for the homeland and the home indoor area. Each of these models also gives us the chance to develop our Plant Recognition Optics and Computer, as well as GPS positioning in a battery-powered, self-recharging, and refueling unit that delivers all-natural ecological enhancements to a far more robust, strong, and fruitful on-site ecosystem. The indoor and outdoor home agrodrones both have long roads of head of them with new development and added features aiding in things like best oxygen levels and quality, and even security for pets and family, and from toxic elements, gases, and intruders.

Model II

This is where things really begin to take off! We can work magic on certain natural areas with the help of the Bio Voltair Final Model. The impact of this development.

• Hydrogen fuel cell for long-duration, zero-emission flights
• High-resolution AI camera system for species recognition
• Precision liquid application system
• Modular design for expansion into seeding, sampling, and surveillance
• Fully autonomous docking/refueling architecture

Target Markets:

• Pioneers of a new human-to-nature culture of a miraculous degree  [invite]
• Regenerative agriculture farms –
• Permaculture and food forestry projects
• Government and NGO reforestation programs
• Private land conservationists
• Ecological restoration contractors

Business Model:

• Hardware Sales: Drones and docking stations, organic formulations, mixing equipment, and fixed systems
• Subscription SaaS: AI mapping and ecosystem analytics dashboard
• Refill Logistics: Organic inputs, batteries, and hydrogen cartridges
• Data Licensing: Ecological data to research institutions and climate orgs

Traction Plan (Next 12–18 Months):

1. Q3: Finalize prototype and onboard AI models
2. Q4: Test flights in Panama (food forest zones)
3. Q1: Deploy in Colombia for pilot customer programs
4. Q2: Begin manufacturing and training operator partners
5. Q3–Q4: Launch dashboard beta and input refill subscriptions

Team:

• Brandon– Team Captain, Ecological Enhancement

The name BioVoltAir is with a favorite quote in mind by VOLTAIR and that is “We are guilty of the good we do not do.”

And there is no doubt we must do this.

• Dr. Richard, E#### – Aerospace Engineer, PhD, current Pentagon Contractor
• [AI/ML Specialist] – Computer vision for plant recognition
• [Operations ] – Logistics, pilot deployments [ChiefBrandon]
• Current Advisors: Include Biotech green energy excecutives, experienced Permaculture legends, Aerospace experts, and working Agricultural, and Mechanical Engineers

Competitive Advantages:

• Battery Powered (self-charging in a programmed route providing a continuous 24/7 working symbiotic enhancements – highest growth rates and strengths ever!) consumer marketplace income
• Hydrogen power ( the next level, longer range, no recharging downtime, highly capable machines), commercial governmental marketplace income
• Closed-loop autonomy (flight + identify + care + refuel)
• Organic and ecosystem-safe payload compatibility
• Real-time data collection and mapping
• Designed for remote deployment

 

Funding Requirements:

• Ask: $650,000 Seed Round
• Use of Funds:
  • 40% R&D and engineering
  • 30% Prototyping and pilot testing
  • 20% Team expansion
  • 10% Legal, IP, and operational setup

Our first drone model

Vision: To deploy millions of intelligent drones across the planet — drones that do not surveil or destroy, but regenerate. With BioVolt Aero, we envision a future where technology partners with nature to create balance, abundance, and ecological restoration at scale.

Hydrogen Fuel Cell Drone for Botanical Management

Project Name (Proposed): Aerobotany

Overview:
An autonomous hydrogen-powered drone designed to identify, monitor, and care for plant species in diverse environments using precision GPS, AI-based visual recognition, and organic nutrient spraying. It autonomously refuels at dedicated hydrogen and fertilizer stations, enabling long-range, sustainable operations in remote areas.

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System Components

1. Propulsion & Power:

• Fuel Source: PEM Hydrogen Fuel Cell
• Energy Management: Lightweight lithium-ion buffer battery for peak loads
• Propulsion: Quad-rotor or hex-rotor architecture

2. Navigation & Mapping:

• System: RTK-enabled GPS module (e.g., u-blox F9P)
• Additional: IMU (Inertial Measurement Unit), barometer, magnetometer
• Autonomy: Path planning via QGroundControl or custom AI layer

3. Botanical Identification:

• Camera: RGB + optional multispectral lens
• Processor: NVIDIA Jetson Nano or Xavier NX
• Model: YOLOv8 or MobileNet trained on local flora dataset
• Capability: Plant species recognition, health diagnostics, maturity estimation

4. Organic Fertilizer Application:

• Tank: 1-2L bladder with quick-disconnect fitting
• Sprayer: Peristaltic pump with precision nozzle
• Trigger: Vision system decision logic initiates spray

5. Refueling & Docking Station:

• Fuel System: Replaceable hydrogen cartridges or high-pressure refill line
• Fertilizer System: Refillable bladder tank with auto-docking connector
• Navigation: AprilTags or beacon-based landing zone
• Charging: Backup solar-assisted electric charging panel

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Functional Workflow

1. Pre-mapped GPS route is uploaded to the drone
2. Drone autonomously navigates and identifies species
3. AI determines health/treatment needs
4. Fertilizer is sprayed as required
5. Flight data and plant analysis is logged
6. Drone returns to station for hydrogen & fertilizer refill
7. Data uploaded to the central ecological management system

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Key Benefits

• Zero-emissions, high-efficiency hydrogen propulsion
• Botanical intelligence for ecological monitoring
• Precision organic treatment with minimal waste
• Operates in remote/agroforestry/permaculture zones
• Supports guerilla permaculture and scalable rewilding

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Phased Development Roadmap

Phase 1: Concept & Design (0-3 months)

• Finalize drone specs
• Create initial marketing material to raise funds for Phase 2 [Drone Build]   COMPLETE [Agriculture Drone Kickstarter]

Phase 2: Prototype Testing (4-8 months)

• Build and test a basic drone with an onboard computer
• Conduct test flights with a dummy payload
• Refuel and fertilizer spray test

Initially, we will be building battery-powered, blanket-spray, ecological area-enhancing models.

Phase 3: Autonomous Integration (9-12 months)

• Enable AI navigation + spray decisions
• Train model with new datasets
• Test complete flight/refuel cycles

This model should be left prepped for more targeted visuals and more GPS-based maneuvers.

Phase 4: Deployment (12+ months)

• Field deployment in jungle/agroforestry sites
• Data integration with ecological platforms
• Refined scale-up for multiple units

 

1. Core Functionalities

• Autonomous Flight using GPS + AI-assisted obstacle avoidance

• Camera-Based Botanical and Elemental Identification (e.g., plant species, animal species, nature changes, river mapping, health measurements, growth stages)

• Liquid Organic Fertilizer Delivery System 

• Hydrogen Fuel Cell Propulsion

• Autonomous Refueling Station

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2. Component Breakdown

A. Hydrogen Fuel Cell System

• Type: PEM (Proton Exchange Membrane) fuel cell – lightweight and suitable for drones

• Tank: Compressed hydrogen cylinder (potentially replaceable or refillable)

• Power Management: Must support camera, GPS, AI chip, spray pump, and flight

• Challenge: Weight-to-energy ratio; ensuring the total payload (fertilizer + equipment) stays light

B. Navigation & Mapping

• RTK GPS Module: High-precision location system (cm-level accuracy)

• Pre-mapped Routes: Based on ecological trails or permaculture layouts

• AI-based dynamic re-routing: Optional real-time route adjustment

C. Plant ID & Health Detection

• Camera: RGB + optional multispectral or thermal for health diagnostics

• AI Model: Trained on a local dataset of regional plant species

• Real-time recognition: TensorFlow Lite, PyTorch Mobile on edge device like NVIDIA Jetson Nano or Coral Edge TPU

D. Spraying System

• Pump: Low-volume precision sprayer

• Tank: Lightweight bladder tank (refillable at the station)

• Targeting: AI-based targeting once the species is identified

E. Refueling & Recharging Station

• Hydrogen Refilling Dock: Replaceable hydrogen cartridges or high-speed refill nozzle

• Organic Fertilizer Tank Refill

• Landing Pad with Visual Markers or Wireless Beacon

References

1. BioVoltAir Home Agriculture Drone Business Plan
2. BioVolt_Aero_Pitch_Deck_Graphic
3. Nutritional_Diversity_Business_Plan

 

Can and should be used in conjunction with the following programs and related potentials.

1. 1. Indigenous Food Systems
   2. Homelessnesss Solutions
   3. War Machine
   4. Guerilla Permaculture
   5. Ecological, Physical, and Mental Health Apps

 

TECHNICALS

BioVoltair: Self-Charging Field Drones for Regenerative Scale

What it is

A family of modular, autonomous ag-drones that:

• Self-charge at solar “nests” (contact rails or inductive pads with battery banks) and/or swap packs at cache stations.

• Fly RTK-GNSS waypoint missions (2–3 cm accuracy) with sensor-guided variable-rate application.

• Hot-swap payload pods: foliar sprayer, dry solids spreader/“seeder,” and selective harvester.

Why it matters

Traditional machinery compacts soil, wastes inputs, and can’t reach steep, wet, or ecologically sensitive ground. BioVoltair swarms deliver precision care with almost zero soil impact, creating more biomass, more biodiversity, and more food—faster and cheaper.

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Core Capabilities

1) Foliar Feeding (Liquids)

• Tank pods: 10–30 L (class-dependent), 50–120 µm droplet spectrum for leaf uptake and microbial teas.

• Throughput: ~8–20 ha/hour per drone (crop and rate dependent) with variable-rate maps from NDVI/multispectral scans.

• Benefits: 20–40% input savings via targeted dosing; faster recovery after stress; higher Brix and micronutrient density.

2) Solids Dropping (Seeds, Inoculants, Biochar, Pellets)

• Hopper pods: 15–30 kg; auger or spinner plates with adjustable gates.

• Throughput: 100–250 kg/hour per drone (material-dependent).
  Example: 10 drones placing 1.0–2.5 t/day of seed-balls, mycorrhizae, or biochar while mapping take.

• Benefits: Rapid reforestation/intercropping without bulldozers; creates new resource flows (timber, fruit, medicine, resins) and carbon sinks.

3) Selective Harvesting (High-Value Light Picks)

• End effectors: soft-grip berry picker, moringa/tea leaf clipper, spice pod clip, pollen/flower collection; vision-guided.

• Use cases: hillsides, terraces, fragile soils, and tree-crown sampling where ladders/tractors are unsafe.

• Benefits: Harvest otherwise “lost” yield; quality picks at ideal ripeness windows (night/dawn missions).

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Autonomy & Self-Charging

• Solar Nest Dock: 1.5–3 kW PV + LiFEPO₄ pack + weatherproof charge pad; contact-rail or inductive landing; 30–60 min top-up cycles (class/pack dependent).

• Battery Cache Option: low-cost swap lockers; robotic arm or human swap in under 60 s.

• Mesh Comms: LoRa for health/telemetry, 5 GHz for video/payload, optional sat-backhaul; automatic relay via ridge repeater.

• Swarm OS: time-windowed waypoint queues, collision avoidance, and recipe engine (e.g., “Tea A at 25 L/ha on NDVI<0.62 zones”).

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Sensing & Precision

• RTK-GNSS + vision-based landing (2–3 cm).

• Multispectral/thermal for canopy vigor, water stress, pest heat signatures.

• LiDAR light for 3D canopy/terrain maps and safe under-canopy passes.

• Closed-loop control: sensor maps → prescription layers → live variable rate.

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Environmental & Production Benefits

• Zero soil compaction; preserves structure, fungi, and water infiltration.

• 50–80% less water vs. ground rigs for foliar work (fine droplets, night missions).

• Chemical reduction via targeted biostimulants and microbial teas; better IPM.

• Access everywhere: steep slopes, wet seasons, wildlife corridors (no road cuts).

• Biodiversity uplift: fast interplanting/seedballing creates multi-strata food forests, compounding yield year-over-year.

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Example Daily Outputs (illustrative, per favorable conditions)

• Foliar feeding: One 20 L-class drone treats 10–15 ha/day at moderate rates; 10 drones = 100–150 ha/day with variable rate.

• Solids dropping: One hopper drone places ~150 kg/day of seed-balls/inoculant; 10 drones = 1.5 t/day (≈100k–200k seed-balls depending on mass).

• Selective harvest: A soft-grip picker drone can clear 40–80 kg/day of high-value berries/leaves from difficult terrain (fleet scales linearly).

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Economics (rule-of-thumb)

• Fleet (10 drones + 4 nests + spares): capex ~“mid five to low six figures” (config dependent).

• Operating cost: electricity from solar + light maintenance; $3–8/ha foliar opex typical at scale.

• Payback levers:

  • Input reduction (20–40%)

  • Yield lift (5–15% first season; more with biodiversity compounding)

  • New product streams from rewilding (fruit, resins, timber, medicinal leaves)

  • Carbon/biomass credits (biochar + reforestation)
    → 12–24-month payback is common in mixed operations.

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Safety & Compliance

• Geofencing + dynamic no-fly zones; ADS-B in where required.

• Redundant power + parachute (octo class); auto-return on wind/rain thresholds.

• Traceability: every drop/seed/harvest point is GPS-time-stamped for audits and certifications (organic, regenerative, biodiversity).

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Product Line (example)

• BioVoltair SCOUT – mapping/NDVI/thermal; 45-min endurance.

• BioVoltair FEEDER – 10–30 L foliar pod; variable-rate micro-mist.

• BioVoltair SOWER – 15–30 kg hopper; seed-ball/biochar/inoculant spread.

• BioVoltair HARVEST – soft-grip/clipper head for berries, tea, moringa, spice pods.

• Solar NEST – autonomous charge dock with mesh gateway and weather station.

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Strategic Impact

BioVoltair lets you grow ecosystems like software: schedule tasks, push “recipes,” receive telemetry, and iterate weekly. The result is vast, decentralized alternative agriculture—food forests, fiber corridors, resin groves, and medicinal understories—that produce tons of natural resources while healing soil and water. No bulldozers. No compaction. Just precise, continuous care.

Growth Rate Expectations

Here’s what you can realistically expect—and why—when you layer (1) daily micro-dose foliars with (2) weekly solid compost + biochar. Ranges assume good water management, decent genetics, and no major pest shocks.

1) Daily foliar feeds (micro-dose, low-salt)

Mechanism: rapid leaf uptake (stomata/cuticle) of amino acids, K, Ca, Mg, and chelated micros; hormones (kelp/cytokinins) push cell division; fulvic acids improve translocation.
Indicative gains vs. no foliars (first 2–4 weeks):

• Canopy expansion / LAI: +10–25% (faster leaf area growth → more photosynthesis).

• RGR (relative growth rate): typically moves from ~0.12 to 0.14–0.15 g·g⁻¹·day⁻¹ (+15–25%).

• Brix (leafy/fruit): +1–3 points; color and turgor improve within 24–72 h.

• Time to first flower/harvest (hort crops): 2–6 days earlier; final yield +8–20% (leafy greens often at the high end).
  How to run it: dawn applications, 50–120 μm droplets; pH 5.6–6.3; 0.2–0.6% total actives (very light, daily). Base with kelp/fulvic/amino + Ca/Mg + chelated micros; add silica 1–2×/wk. Avoid evenings (disease risk). Pause during heat spikes or when leaves are wet.

2) Weekly compost + biochar (soil engine)

Mechanism: compost supplies biology + slow nutrients; biochar adds permanent pore space to hold water, air, and ions; together they boost root volume, mycorrhizae, and water-use efficiency.
Indicative gains vs. no soil amendment (first season):

• Root mass / root length density: +15–40% (biggest on sandy/acid soils).

• Water-use efficiency: +10–20%; plants hold through dry spells longer.

• Vegetative growth rate: +10–30%; stem caliper and internode strength improve.

• Yield: +10–35% in year 1; +20–60% by year 2 as biochar “charges” and microbial networks mature.
  How to run it: top-dress weekly micro-doses around the dripline: compost 0.5–1.5 L/plant (or 0.5–1.5 t/ha·wk in beds), lightly incorporated or mulched. Biochar: pre-inoculate in compost tea/manure for 24–72 h; apply 5–10 t/ha once (establishment) then 0.5–1 t/ha quarterly as top-up.

Synergy & quick recipe

Used together, foliars (fast leaf) × soil (deep root) typically deliver combined growth-rate gains of ~20–45% and yield lifts of ~25–50% over a season (degraded soils can see more).
Starter program (hort crops):

• Daily foliar: kelp (50–100 ppm), fulvic (100–150 ppm), amino N (0.05–0.1% N), Ca 50–100 ppm, micronutrient chelate (label-rate), silica twice weekly.

• Weekly soil: 1 L mature compost + 100–200 mL inoculated biochar per m² (scale to crop/row), plus mulch.

• Monitor: SPAD (chlorophyll), Brix, stem caliper, soil moisture/EC. If SPAD > target or edges burn, cut foliar strength by 25–50%.

Species (leafy greens, tomatoes, cacao, moringa, etc.) and soil texture readings allow the system to dial in exact rates and a 6-week schedule.

6-Week Regenerative Acceleration (Filled Example)

A) Daily Foliar (micro-dose, dawn runs)

Tank size example: 100 L (scale linearly)
Target pH: 5.8–6.2 Droplet: 80–120 µm Height: 2.5–3.5 m AGL Speed: 3.5–4.5 m/s

Per 100 L tank (final, ready to spray):

• Hydrolyzed amino-N (12% N): ≈ 417 mL (gives ~500 ppm N total)

• Kelp extract (liquid, standard concentrate): 150 mL (≈ 75–100 ppm cytokinins)

• Fulvic acid (liquid, 12%): 100–150 mL (≈ 120 ppm fulvic)

• Calcium chelate (5% Ca): 180 g (→ 90 ppm Ca)

• Epsom salt (MgSO₄·7H₂O): 50–60 g (→ 50 ppm Mg)

• Micronutrient chelate mix (Fe/Mn/Zn/B/Cu): label rate × 0.5 (typically 50–100 g)

• Potassium silicate (liquid) 80 mL, 2×/week (Wed/Sat) only

• Non-ionic wetting agent: 0.05% v/v (≈ 50 mL)

Rules of use

• Spray at first light; pause if leaf surface > 28 °C or dripping wet.

• Skip amino component during heat spikes; keep Ca/fulvic/kelp.

• If leaf-edge burn or SPAD > target, cut amino dose 25–50% for 3 days.

Expected response (weeks 1–4):

• Leaf area index +10–25%, RGR +15–25%, Brix +1–3.

• Time-to-flower/first cut 2–6 days earlier; yield +8–20% (crop-dependent).

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B) Weekly Solids: Compost + Biochar (soil engine)

Default establishment (once at start):

• Biochar 7 t/ha (pre-inoculated 48 h in compost tea: water:char 10:1 + 1% molasses)
  → Field cue: 0.7 kg/m² banded along rows, then mulched.

Weekly top-dress (every Monday):

• Compost: 1.0 t/ha·wk → 100 g/m² lightly incorporated or mulched at dripline.

• Biochar top-up: 0.25 t/ha·wk → 25 g/m², use inoculated char (as above).

• Moisture rule: water to field capacity after top-dress if rainfall < 10 mm.

Expected response (season 1):

• Root mass +15–40%, water-use efficiency +10–20%, vegetative growth +10–30%, yield +10–35%.

• Season 2: as biochar “charges,” yield gain often +20–60%.

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C) “By Crop” quick scalers

• Leafy greens beds: compost 120–150 g/m²·wk; keep daily foliar full-strength; silica 2×/wk.

• Tomato/pepper rows: compost 80–120 g/m²·wk; keep Ca at 90–120 ppm (bump Ca chelate to 240 g/100 L during fruit set).

• Tree/perennial (cacao/moringa/fruit): ring-top-dress 1–2 L compost/plant·wk + 0.3–0.6 L inoculated biochar/plant·wk; foliar as above but every other day once canopy is dense.

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D) BioVoltair mission presets (ready to upload)

Mission 1 — FOLIAR_DAILY_A

• Pattern: boustrophedon, lane overlap 30%

• Airspeed 4.0 m/s, AGL 3.0 m, droplets 100 µm

• Variable-rate map:

  • NDVI < 0.62 → 125% dose

  • NDVI 0.62–0.75 → 100% dose

  • NDVI > 0.75 → 70% dose

• Window: Civil dawn → +2 h; wind cutoff ≤ 3.5 m/s; RH > 55%

Mission 2 — SOLIDS_WEEKLY_A (Mon)

• Hopper gate calibrated to deliver 100 g/m² compost + 25 g/m² biochar

• AGL 4.5 m, speed 5.0 m/s, pass spacing 3.0 m (adjust to bed width)

• Skip no-drop zones: drains, stream buffers ≥ 15 m

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E) Monitoring & go/no-go gates

• SPAD (leaf chlorophyll): target band 42–50 (greens), 38–46 (tomato); if +5 over target, cut amino 25%.

• Brix: weekly leaf/fruit; rising trend = good; flat + high EC → reduce salts.

• Stem caliper / internode length: weekly; elongation without caliper gain → raise Ca + silica.

• Soil EC & moisture: keep EC < crop threshold; never let top-dress sit dry > 24 h.

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F) Safety & compliance

• No sprays in direct sun/heat; no-spray within 15 m of open water.

• Use PPE for concentrates; verify organic/regenerative inputs list for audit.

• All drops/time-stamps logged to RTK track for traceability.

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G) What you gain (combined effect)

• Growth-rate uplift: ~20–45% typical;

• Yield lift: ~25–50% over a season on average/degraded soils;

• Resource efficiency: 20–40% input savings via precision foliars + biological soil engine;

• Resilience: deeper roots, better Ca/Mg status, higher Brix → lower pest/disease pressure.