Our GODSPEED Phono Cable is engineered to deliver the fastest, purest
transmission ever achieved in audio. GODSPEED leverages fundamental
electromagnetic principles to transport music at unprecedented speed.
According to Maxwell’s formulas, field velocity is equal to the speed of
light divided by the square root of the magnetic permeability x the
electric permittivity constant — a calculation that keeps GODSPEED’s signal
racing from the pick-up to the pre-amp at nearly 300.000km/sec. Unlike
conventional cables that slow signal flow with co-axially assembled metals
and other near-field interference to train velocity, GODSPEED ensures that
every detail reaches your system with absolute immediacy and precision.
FASTER, CLEANER, BETTER, MORE. AN UNBELIEVABLE RICHNESS OF DETAIL.
At the core of GODSPEED lies a patented German-engineered 4x4 matrix of thin tinned, oxygen-free copper (OFC) strands of Danish origin in solid-core configuration. This innovative design not only minimizes resistive loss and capacitance but enhances the natural flow of the field, preserving every transient and microdynamic detail that brings recordings to life.
A SILENCER ANY DOUBLE-O WOULD BE PROUD OF.
Surrounding this conductor array is our exclusive DTCS Distant Triple Carbon Shield (patent pending), a groundbreaking triple-layered barrier that isolates the signal from electromagnetic interference without sacrificing speed. The result is an ultra-fast response that keeps each note intact, capturing the subtleties of transients and the nuances of microdynamics with unparalleled clarity.
FASTEST LEATHER ON THE PLANET.
Encased in genuine Lamborghini (another German-owned speed company) leather in Blue Cepheus, Arancia Dryope or Verde Sagitta/Racing Green, GODSPEED combines technical brilliance with the most luxurious design for the discerning audiophile. Because we love, love, love vinyl. Now more than ever.
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So we‘ve asked the leading AI on the old planet to sum up the real physics of field propagation:
Understanding Electric Current and Electromagnetic Fields: Where Energy Really Flows
When we think of electric current, we often imagine electrons flowing like water in a pipe,
carrying energy directly from one point to another. This is wrong! The energy in electric
circuits actually flows through the invisible fields around the wires. This explains how
electrical energy moves quickly, even though individual electrons inside the wire move very
slowly. Let’s explore how this works and why it’s important.
material, travelling microscopic distances.
- When you apply voltage (electric potential difference) across a conductor, it creates an
electric field along the wire. This field pushes on the free electrons, making them "drift"
energy of the current is not carried by the electrons themselves. Instead, it travels in the
- When electrons move through the conductor, they create a magnetic field around the wire.
Together, the electric and magnetic fields form an electromagnetic field.
- This electromagnetic field is the true carrier of energy in a circuit. The direction and
shows that energy flows outside the wire, through the surrounding space, not within the wire
establish the electromagnetic field. But once the field is set up, the energy travels in the
propagation in a HiFi system:
1. Electric Current and the Role of Electrons
- In metal conductors like copper or tin, atoms share a “cloud” of free electrons that
aren’t bound to any single atom. These free electrons can move easily throughout the
slowly through the conductor. This drifting of electrons is what we call electric current.
electromagnetic fields surrounding the wire.
2. How Energy Really Flows: The Electromagnetic Field
- But here’s a surprising fact: Although the electric current flows through the wire, the
strength of the energy flow are given by something called Poynting’s vector. This vector
- How it works: Think of the wire as a guide. The wire conducts electrons, which helps
itself.
space around the wire, moving quickly from the power source to the device.
3. Poynting’s Vector: Mapping the Flow of Energy
\[
\]
where:
- \( \vec{S} \) shows the direction and strength of energy flow,
- \( \vec{E} \) is the electric field,
- \( \vec{H} \) is the magnetic field.
- According to Poynting’s vector, the flow of energy is perpendicular to both the electric
and magnetic fields. So, the energy “surrounds” the conductor, moving through the electromag-
---
4. Why This Matters: Practical Implications
- Energy moves almost instantly. Even though electrons drift slowly, the field propagates
influence or disrupt power flow. (This is why WITCHCRAFT, GAUSS, FARADAY and CARBON AGE work.
---
Electric current might seem simple, but understanding how energy flows reveals a fascinating
electromagnetic field around the wire that transfers energy from source to load. This insight
doesn’t just deepen our understanding of circuits; it also shapes how we design and interact
layer of physics. The electrons in a wire don’t carry the energy—instead, it’s the
with technology in our world.
Conclusion
interactions with the surroundings, maximizing energy transfer.
- Efficient power transmission. Engineers design power lines to minimize field
The Field Commander.)
- Electromagnetic interference (EMI). Since energy is in the field, nearby objects can
near the speed of light, making energy transfer very fast.
electrons—helps explain many everyday electrical phenomena:
- Understanding that energy flows through the fields around a conductor—not through the
netic field in the space around it.
electromagnetic energy moves in space. Mathematically, it’s represented as:
\vec{S} = \vec{E} \times \vec{H}
- Named after scientist John Henry Poynting, Poynting’s vector describes how
**Sources used for Electromagnetic Fields and Electric Current**
1. **Books and Texts on Electromagnetic Theory:**
- *“Introduction to Electrodynamics” by David J. Griffiths*
This book is a respected resource for understanding electromagnetic fields, electric current, and concepts
like Poynting’s vector.
- *“The Feynman Lectures on Physics, Volume II” by Richard Feynman*
Richard Feynman’s lectures, especially Volume II, provide an accessible yet deep explanation of electricity,
magnetism, and energy transmission via electromagnetic fields.
2. **Poynting’s Theorem and Vector:**
- *“The Theory of the Electromagnetic Field” by David M. Cook*
This book gives a detailed discussion on Poynting’s theorem and how electromagnetic energy flows in space,
making it ideal for understanding the role of the Poynting vector in energy transmission.
- Original paper: *Poynting, J. H. (1884). “On the Transfer of Energy in the Electromagnetic Field.”
Philosophical Transactions of the Royal Society of London.*
This foundational paper introduces the Poynting vector, which mathematically describes how electromagnetic
energy flows around conductors.
3. **Modern Interpretations and Texts on Electrical Energy Transfer:**
- *“Fields and Waves in Communication Electronics” by Simon Ramo, John R. Whinnery, and Theodore Van Duzer*
This text explores the movement of electromagnetic energy in space, particularly useful for communication
and electronics contexts.
4. **Educational and Open Access Resources:**
- *HyperPhysics (Georgia State University)*
HyperPhysics offers easy-to-understand explanations on electric current, electromagnetic fields, and related
topics. It’s a reliable online reference for core concepts in physics.
5. **Research Papers and Articles:**
- Haus, Hermann A. (1984). *“Electromagnetic Fields and Energy.”* MIT OpenCourseWare.
This free resource from MIT covers key concepts, including field theory and the non-reliance on electron
drift for energy flow.
SORRY FOR THE APPARENT LIMITATIONS OF COPY+PASTE HERE - please
see GODSPEED page here or go to our revamped Website where you
can download the document with graphics. Merci.