Animal Navigation a new theory for 2025

How animals navigate has been a mystery forever. At present, the prevailing theory is that animal navigation is based on magnetic information. But there are huge problems with this approach. In order to use the Earth’s magnetic field to navigate by, you need to know where you are and where you are going, as well as how this relates to the magnetic field. Originally, people studying this thought that this was like a compass bearing, but now the idea is that the animals use the angle of dip of the magnetic field. The magnetic field rises at the poles vertically and curves around the world, being parallel at the equators.

Problems With the Magnetic Field Theory

This magnetic theory is a problem, as many of the birds that migrate nest in the Arctic and migrate to warmer climes in the winter. But using the magnetic field for direction-finding does not really work as the field is vertical. So how do the birds know where to go?

I think that they access an enormous database held in a huge intelligent plasma cloud existing between the Earth and the Moon: the Kordylewski cloud. In a book called The New Science of Heaven by Robert Temple, he postulates that this intelligent cloud has held data on everything since the creation of the Earth.

With the rise of Artificial Intelligence, we are getting more and more used to the idea that we can have hugely intelligent computers, so the idea of a plasma cloud having an amazing intelligence is not such a step.

Dowsing and Accessing Information

As well as my interest in animal navigation, I am a dowser. The art of dowsing is to bypass the bossy frontal cortex to get answers to our questions. Animals do not have the huge frontal cortex that we do, so they should be able to get information more innately and easily than we do.

Innate Access to a Universal Database

I propose that migrating animals are born with access to this database (not inhibited by a frontal cortex that knows better), and so “know” where they are to go. Perhaps navigating is rather like acting on the answer got from a Google search: “Where do I need to go?”. There is certainly constant feedback nudging the animals to keep on track to make their destination.

For instance, cuckoos are interesting. When the birds fledge, they fly to their wintering grounds in the Congo Basin. They go alone from nests all over Europe and still they all make it to the Congo. They can only do this if they have knowledge (information) of where they need to go and how to get there.

Homing pigeons seem to get home from places they have never visited, yet they still make it home to their lofts. Navigation is difficult, so all animals use any information that is available to them, like landmarks, to help them on their way. Homing pigeons use landmarks and smell, but they only “know” about the area around their lofts and any areas they have come across on their training flights.

Evidence From Dowsing Practice

Here are some reasons why I think there is an overarching database holding all knowledge. If asked to dowse around a person’s house to discover the location of all the services running in and out of it, you engage your thoughts and brain with the cloud and ask for the location of what you are thinking about, for instance the mains water feed, and you can find it. This means you can locate each service individually in turn: gas, electric feed, mains water in, sewage out, your septic tank and internet feed, etc. You can also follow pipes, too, and are led back to your chosen pipe if you drift off the route, to get you back on track.

Summary

Whilst the scientific community believes that animal navigation is based on sensing the magnetic field, this theory does not answer many questions, such as how the cuckoo knows which way to go. It is not a straight journey and needs information such as where they refuel to get enough energy to cross the Sahara Desert. The way home to breed the next season is often different from the journey down.

If animals can access a huge intelligent database which knows where they are and where to go, then all their problems are solved. Modern science, such as quantum physics, is already probing these questions with problems like Albert Einstein’s “spooky action at a distance”, where two entangled particles, however far apart, if one changes, the other matches the change exactly.