Quantum Sphere Helios 2
Activate Plant Performance.
At Scale.
QS Helios 2 is Fidelio’s next-generation acoustic biotechnology system, designed to enhance photosynthesis, strengthen plant resilience, and support healthier soils—without chemical inputs. Engineered for real-world deployment, it delivers measurable biological impact across vineyards, farms, and restoration sites.
Built on years of field research and iteration, QS Helios 2 operates through precisely calibrated sound and vibrational patterns that work with plant physiology. One system can support up to 10 acres, offering a scalable, energy-efficient solution for growers and land stewards seeking performance, sustainability, and long-term resilience.
Discover how QS Helios 2 can transform your fields.
Our Mission
Activate the hidden intelligence of living systems—at scale.
Fidelio is an innovative, community-driven deeptech project developing a new approach to plant regeneration: instead of acting through chemical inputs or genetic modification, we work through precisely engineered physical signals—sound and vibration patterns designed to interact with plant physiology, soil biology, and ecosystem dynamics.
Modern agriculture is reaching a biological ceiling: increasing dependence on inputs, declining soil vitality, and rising climate stress. Fidelio explores a third pathway—biological activation. By stimulating photosynthesis, root function, and soil activity through controlled acoustic protocols, we aim to help plants and soils express their intrinsic capacity for resilience and performance—while preserving genetic identity and ecological balance.
Grounded in field experimentation and measurable observation—including deployments in mature vineyards in California’s Russian River Valley—Fidelio documents change through comparative plots, agronomic monitoring, and biochemical indicators (e.g., juice composition). We do not promise miracles. We measure biological change.
Our long-term vision is to build a scalable, energy-efficient “signal layer” for agriculture and ecosystem restoration—supporting regenerative viticulture, farming, forestry, and research worldwide, with technology designed to amplify life rather than replace it.
RESEARCH
Engineering the Physics of Plant Life
Fidelio investigates how physical signals—sound and vibration—can influence biological processes in plants, soils, and ecosystems. Our research is rooted in a simple hypothesis: beyond chemistry and genetics, living systems respond to structured physical information.
Rather than treating sound as a metaphor or a symbolic stimulus, Fidelio approaches it as a measurable biological variable, capable of interacting with photosynthesis, root architecture, soil microbiology, and plant adaptive behavior.
From Inputs to Signals: A New Scientific Question
Conventional agronomy operates primarily through chemical and genetic interventions. Fertilizers, pesticides, and breeding programs have shaped modern agriculture, but they leave a largely unexplored dimension of biology untouched: the role of physical signals in regulating living systems.
Fidelio explores this third dimension.
Our research asks:
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Can acoustic patterns modulate photosynthetic efficiency?
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Can vibrational signals influence root development and nutrient uptake?
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Can sound affect soil microbial dynamics and vegetation patterns?
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Can physical signals enhance plant resilience without altering genetic identity?
These questions define a new research frontier at the intersection of biology, physics, and signal engineering.
Evidence from Mature Ecosystems
A central focus of Fidelio’s research is the study of mature biological systems—ecosystems traditionally considered stable and difficult to modify.
In multi-decade vineyards in California’s Russian River Valley, Fidelio has observed:
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Structural changes in vine growth patterns
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Emergence of new fruit-bearing formations in mature plants
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Increased vigor under dry-farming conditions
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Spatial changes in soil vegetation distribution
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Variations in biochemical profiles of grape juice
These observations are analyzed through comparative methods rather than isolated anecdotes. Fidelio does not claim universal causality; it documents reproducible biological phenomena and investigates their mechanisms.
Toward a Signal-Based Biology
Fidelio’s research suggests that physical signals may constitute an underexplored layer of biological regulation—complementary to chemical and genetic processes.
If confirmed and refined, this perspective could reshape how agriculture, ecology, and plant science understand intervention in living systems.
Rather than forcing biological change through external inputs, signal-based biology explores how to activate latent capacities already embedded in living organisms.
A Living Research Platform
Fidelio is not a closed laboratory project. It is an evolving research platform where technology, field experimentation, and scientific inquiry continuously inform each other.
Our ambition is not to replace conventional agronomy, but to extend it—by opening a new scientific domain where biology, physics, and ecology converge.
We do not engineer plants.
We study how to activate life
Regenerating 30 years old Vineyard
Use Case | March 2023 – January 2025
Location
Daro Vineyard
California, Russian River Valley
Dry-farmed Pinot Noir vineyard (30+ years old)
Overview
From March 2023 to January 2025, Fidelio deployed its plant-centered acoustic technology in a 30-year-old dry-farmed Pinot Noir vineyard in California.
The objective was not to change farming practices or increase inputs, but to support plant physiology and soil biological activity in a mature vineyard already performing near its historical ceiling.
Over two growing seasons, the vineyard showed:
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a significant increase in yield,
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no additional irrigation or chemical inputs,
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and persistent biological signals visible at the soil surface, extending well beyond harvest.
Context & Starting Point (Pre-2023)
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Mature Pinot Noir vines (30+ years), dry-farmed
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Baseline production around 4.5 tons per acre, already considered solid for dry farming
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Increasing climatic stress (heat variability, water limitation)
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Desire to improve resilience and performance without altering genetics, irrigation, or soil inputs
Deployment Timeline & Results
Phase 1 — Initial Activation (March – October 2023)
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RegenApp frequencies deployed across a defined block of the vineyard
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No changes to:
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irrigation (none),
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fertilization,
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pruning,
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or cover crop management
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Continuous operation during the active growing season
Observed effects
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Improved vine uniformity within the treated zone
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Strong photosynthetic activity despite dry conditions
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Balanced vegetative growth consistent with mature vines
Phase 2 — Yield Progression (Harvest 2023 → 2024)
Following deployment:
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Yield increased from ~4.5 tons per acre to 6 tons per acre
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Achieved under dry-farming conditions, without additional inputs
For 30-year-old Pinot Noir vines, this increase is agronomically significant.
It indicates not only higher productivity, but improved system efficiency rather than overstimulation.
Phase 3 — Juice Panel & Fruit Quality (Harvest 2025)
The 2025 juice panel provided an important qualitative confirmation of the system’s balance.
Key observations from the juice analysis included:
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Good sugar–acid balance, consistent with controlled ripening
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Stable acidity, supporting freshness and structure
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Well-developed phenolic expression, without excessive extraction potential
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No signs of dilution or stress-related imbalance, despite higher yields
These results are particularly relevant because they show that:
➡️ increased yield did not come at the expense of juice quality.
In mature Pinot Noir, this balance is difficult to achieve and often compromised when yields rise.
Phase 4 — Soil Expression & Persistence (2024 → January 2025)
Beyond vine performance, a clear signal emerged at the soil surface:
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A dense, uniform cover of brome grass developed within the treated area
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Dominance decreased progressively with distance from RegenApp coverage
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In the adjacent untreated field:
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brome was present, but not dominant
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Outside the vineyard:
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brome largely disappeared
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This spatial pattern persisted through January 2025.
Interpretation: A Biological Indicator of System Activation
Brome is a fast-responding species that thrives when:
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root activity is high,
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soil microbiology is active,
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nutrients already present in the soil become more available.
In this vineyard, the surface area covered by brome functioned as a living indicator of where the soil–plant system was most active.
Rather than being introduced or forced, vegetation self-organized in response to localized soil conditions linked to plant physiological activity.
This provided a rare opportunity to:
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infer the effective zone of influence of RegenApp,
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observe persistence beyond harvest,
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and connect yield, juice quality, and soil biology into a single coherent system response.
Key Outcomes (March 2023 – January 2025)
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Yield increase from 4.5 to 6 tons per acre under dry farming
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Maintained juice quality and phenolic balance at higher yield
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No irrigation, no chemical inputs, no genetic modification
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Persistent soil biological activation visible through vegetation patterns
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Clear spatial differentiation between treated and untreated areas
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Effects observable beyond the growing season
Technologies can support agriculture by amplifying natural processes, rather than replacing them
Summary
This 30-year-old Pinot Noir vineyard did more than improve its yield.
From March 2023 to January 2025, it demonstrated that:
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a dry-farmed system can move from 4.5 to 6 tons per acre,
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maintain juice quality and phenolic integrity,
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and leave a visible, persistent signature in the soil itself.
The vineyard did not just perform better.
It revealed how a living system responds — and remembers — when its natural processes are supported rather than forced.
SOLUTION
QS HELIOS 2
QS HELIOS 2 is a state-of-the-art, Bluetooth-connected device designed to emit specific musical frequencies that positively influence plant growth by enhancing photosynthesis. Equipped with a high-quality Bluetooth speaker, the Quantum Sphere covers up to 10 acres, making it ideal for both small-scale and large agricultural settings.
By broadcasting frequencies carefully selected to interact with plant biology, QS HELIOS 2 helps plants absorb more light energy, boosting their photosynthesis efficiency, growth, and overall resilience.
Regen App
Our Regen Android application is the core of this experience, allowing users to control and customize the musical frequencies sent to their plants. With a user-friendly interface, Regen provides the flexibility to select different sound wave patterns and frequencies tailored to specific plant types or growth stages.
The app connects directly with the Quantum Sphere via Bluetooth, giving users full control over the frequency output and enabling real-time adjustments.
Why Combine the Two?
The power of our technology lies in the synergy between QS HELIOS 2 and Regen. While Regen enables users to customize and tailor frequency settings, QS HELIOS 2 amplifies these frequencies across expansive crop areas, allowing entire fields to benefit from this technology. The combination provides a unique, scalable solution that is both accessible and adaptable for gardeners, farmers, and agricultural professionals alike.
Transformative Benefits:
Enhanced Photosynthesis
The musical frequencies emitted encourage plants to maximize their photosynthetic capacity, leading to healthier, faster-growing crops
Scalability
Covering up to two acres, this technology is adaptable for various environments and scales, from small gardens to large farms.
Ease of Use
Simply set up the Quantum Sphere, connect it to the Regen app, and customize your frequencies to begin transforming your crops.
