Alien Reproduction Vehicle

[Nwakuche]

I live on $100 a month, and just making things work as far as that goes. I am not a source of money. would take me a long time to save up that much.
your description is plenty enough to try it, or at least likely it is.
I have 2 people that have given me full schematics of such a device, just have not built it yet.
so many experiments to try and so many other things I need to get done in life (I run a farm)

the central DC magnetic field in the center of the MAGVID is the real cost of the experiment, without that, it would be way easier.
I will try to run your idea and will share results when I have them.
I wish you good luck with your work.

I will attach a link to the schematic of my MAGVID sine wave inverter when i am done with the design. it is very simple and apart from the central controller (raspberry pi) and the magnetic core for the rotating magnetic field system,the rest are not expensive. Opetating frequency of proposed design is 13.65 MHZ. No usage of central magnetic field as it is not necessary.

The output wire can carry more load than you would expect from the size of the wires. This is due to the fact that electrons in the output being moved by the rotating magnetic field undergo spiraling motion instead of a zig-zag motion. This spiral motion causes magnetic attraction between conduction electrons and protons in the metal wire, so they move as one unit relativly and resistivity is reduced. The reduction in the relative resistance of the output wire due to the rotating magnetic field is inversely proportional to drive frequency.

 

[Nwakuche]

I live on $100 a month, and just making things work as far as that goes. I am not a source of money. would take me a long time to save up that much.
your description is plenty enough to try it, or at least likely it is.
I have 2 people that have given me full schematics of such a device, just have not built it yet.
so many experiments to try and so many other things I need to get done in life (I run a farm)

the central DC magnetic field in the center of the MAGVID is the real cost of the experiment, without that, it would be way easier.
I will try to run your idea and will share results when I have them.
I wish you good luck with your work.

For the microcontroller to generate the two phase rotating magnetic field, you can use raspberry pi Zero.
IXRFD615 mosfet driver in h bridge configuration to power the series LC circuit.

remember, there are two pair of coils. Each coil in a pair facing directly each other and are at right angle to the other pair. Each coil in a pair can be either wired in series or in parallel forming an inductor.
Each pair of coil should be connected in series with a capacitor to form a series LC circuit, so you will have two pair of series LC circuit.
Drive power to the pair of series LC circuit should be controlled by the microcontroller. This is done by programming the microcontroller to adjust frequency to the series LC circuit i.e four coil two phase system.
FOR LOW DRIVE POWER
Adjust frequency to be out of tune with the LC circuit.
FOR HIGH DRIVE POWER
Adjust frequency to be in tune with the LC circuit.

i am very interested in the MAGVID related principles because therein lies the path to the philosopher stone.

Did you notice that the effects of the electrostatic/MAGVID device remain in one location even after the device have left the location. This is at low power.

SO IMAGINE Then Remanant Effects on suitable Materials like WATER at High POWER.
This is most likely the starting point to make the philosopher stone.

 

[Nwakuche]

To stand against the powers that be we would need personal defense devices while working on these life changing technologies. So the order of priorities should be
1. Build the MAGVID device and confirm the theory.
2. Make the philosopher stone and convert lead to Gold because you will need a lot of resources for the work at hand.
3.Build a personal protective devices , develop other life changing technologies, remain underground until humanity is matured enough emotionally and mentally to avoid blowing themselves to bits as they have done with previous technologies.
4. Seek out those who are worthy and build a community to replace the present ones here on earth and hide in plain sight until these objective is done.

 

[nivek]

View: https://youtu.be/yUFYnVXbLoY


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[Nwakuche]

View: https://youtu.be/yUFYnVXbLoY


.

UPDATE

1.nickel zinc soft ferrite (CMD5005) should be used as it can be used at high frequency. As you are using it as an open core inductor, the effective permeability should be relativily constant from low to high power making operation reliable. NB: Get a LCR meter to determine the effective permeability.
2. reduce operating frequency to 3MHZ.
use four steps pwm (pulse width modulation) with LC filter to get pure sine wave.
3. while using raspberry pi, use library wiringpi hardware pwm as it has four gpio configured for that

There are a lot of things to do to ensure a successful project.As i dont have the required funds, i can only postulate i.e. i will need a sample of the soft ferrite to determine open core permeability.

i will also need raspberry pi zero to ensure that any code i write actually works as it used. Simulation can only take you so far.

i will also need an oscilloscope and other things not mentioned.

Schematic of a device has its limits. Unless you are well knowledgable in electronics, you will have serious difficulties. Typically it is good to build only on a working schematic as you are sure of help if you need it expect you are already good with electronics.
Though this write up is specifically addressed to spacecase0

it will take a lot of time to build a manual and i am not too good with corel draw.

When i have a working device, then i will post a full explanation for others to replicate so that i will be able to answer any questions or help with replications.

 

[spacecase0]

UPDATE

1.nickel zinc soft ferrite (CMD5005) should be used as it can be used at high frequency. As you are using it as an open core inductor, the effective permeability should be relativily constant from low to high power making operation reliable. NB: Get a LCR meter to determine the effective permeability.
2. reduce operating frequency to 3MHZ.
use four steps pwm (pulse width modulation) with LC filter to get pure sine wave.
3. while using raspberry pi, use library wiringpi hardware pwm as it has four gpio configured for that

There are a lot of things to do to ensure a successful project.As i dont have the required funds, i can only postulate i.e. i will need a sample of the soft ferrite to determine open core permeability.

i will also need raspberry pi zero to ensure that any code i write actually works as it used. Simulation can only take you so far.

i will also need an oscilloscope and other things not mentioned.

Schematic of a device has its limits. Unless you are well knowledgable in electronics, you will have serious difficulties. Typically it is good to build only on a working schematic as you are sure of help if you need it expect you are already good with electronics.
Though this write up is specifically addressed to spacecase0

it will take a lot of time to build a manual and i am not too good with corel draw.

When i have a working device, then i will post a full explanation for others to replicate so that i will be able to answer any questions or help with replications.

I did electrical engineering work for a few years, mostly analog circuits and cmos chips, have not played much with computers or TTL logic.

I have an arbitrary waveform generator, they are quite handy, but making your own with a raspberry pi should work better as you will have more control of what it does. I can get my generator to work, it is just scanning frequencies is very very slow...
an oscilloscope is quite handy for prototyping things, if you are dealing with low enough frequencies you might be able to use the sound input of a computer (or phone) and display it on that, some free software is out there for that.
I will give you all the tech help I can.
did I already share this version of magvid ?
US patent US20030209636A1

US20030209636A1 - Bobbin electromagnetic field propulsion vehicle - Google Patents

This invention relates to a spacecraft which generates its own magnetic moment and magnetic field gradient in order to produce lift on the hull. The magnetic moment is generated by a large area solenoid located in the hull. A toroidal core wrapped with electrical bobbins at intervals along said...

patents.google.com

 

[spacecase0]

View: https://youtu.be/yUFYnVXbLoY


.

the youtube app kept crashing through me watching that,
I love that guys videos,
kind of seems like youtube is making sure less and less people see him the last few months

 

[Nwakuche]

UPDATE
Avoid using raspberry pi as it does not have sufficient number of dedicated hardware pwm gpio pins for the MAGVID device. We need up to four independent pins and it has just two. Use Teensy 4.1 development board available from Teensy® 4.1 for this project as it has up to 22 independent channels for hardware pwm.

maximum frequency that you can drive the MAGVID inverter with this board is 2.3mhz with 8 steps sinusoidal pulse width modulation (SPWM).
After much consideration for the MAGVID inverter in-order to reduce complexity of required coding relatively, don't bother with power control using the micro-controller, just use a fixed frequency and place a variable resistor in series with the power supply going to the four coil system to control power being fed to the rotating magnetic field. Since you are using high frequency, even with low current, induced E.M.F per turn for the output coil will still be high.

Equation to calculate the output voltage is Vout = N*(B*A/F) where N =number of turns of output coil, B =magnetic field strength in Tesla, A =area of side of soft ferrite magnetic core or air-core inductor facing the output coil, F =frequency of the rotating magnetic field

NB: In one cycle, the rotating magnetic field completes on revolution.

 

[Nwakuche]

UPDATE
Avoid using raspberry pi as it does not have sufficient number of dedicated hardware pwm gpio pins for the MAGVID device. We need up to four independent pins and it has just two. Use Teensy 4.1 development board available from Teensy® 4.1 for this project as it has up to 22 independent channels for hardware pwm.

maximum frequency that you can drive the MAGVID inverter with this board is 2.3mhz with 8 steps sinusoidal pulse width modulation (SPWM).
After much consideration for the MAGVID inverter in-order to reduce complexity of required coding relatively, don't bother with power control using the micro-controller, just use a fixed frequency and place a variable resistor in series with the power supply going to the four coil system to control power being fed to the rotating magnetic field. Since you are using high frequency, even with low current, induced E.M.F per turn for the output coil will still be high.

Equation to calculate the output voltage is Vout = N*(B*A/F) where N =number of turns of output coil, B =magnetic field strength in Tesla, A =area of side of soft ferrite magnetic core or air-core inductor facing the output coil, F =frequency of the rotating magnetic field

NB: In one cycle, the rotating magnetic field completes on revolution.

CORRECTION
THE EQUATION SHOULD BE Vout = N*(B*A/(1/F))

(1/F) = T where T = Time taken to complete one revolution of the rotating magnetic field.

 

[Nwakuche]

Output coil should be wrapped around each of the four coil system that generates the rotating magnetic field. This should be obvious if you consider the MAGVID material as it shows the direction of induced emf due to the rotating magnetic field.
As i said before, the central magnetic field is not needed for the Inverter version of the MAGVID device.

 

[Dejan Corovic]

UPDATE
Avoid using raspberry pi as it does not have sufficient number of dedicated hardware pwm gpio pins for the MAGVID device. We need up to four independent pins and it has just two. Use Teensy 4.1 development board available from Teensy® 4.1 for this project as it has up to 22 independent channels for hardware pwm.

maximum frequency that you can drive the MAGVID inverter with this board is 2.3mhz with 8 steps sinusoidal pulse width modulation (SPWM).
After much consideration for the MAGVID inverter in-order to reduce complexity of required coding relatively, don't bother with power control using the micro-controller, just use a fixed frequency and place a variable resistor in series with the power supply going to the four coil system to control power being fed to the rotating magnetic field. Since you are using high frequency, even with low current, induced E.M.F per turn for the output coil will still be high.

Equation to calculate the output voltage is Vout = N*(B*A/F) where N =number of turns of output coil, B =magnetic field strength in Tesla, A =area of side of soft ferrite magnetic core or air-core inductor facing the output coil, F =frequency of the rotating magnetic field

NB: In one cycle, the rotating magnetic field completes on revolution.

Great post. Thank you for writing this.

I would like to add that the route you suggested is not the only one. There are lots of ADCs & DACs on the market that can be managed through I2C or even better SPI interface. These devices can then produce waveform that you choose by setting only a few defining parameters over the interface and you can have several such devices on the interface chain. And these devices cost typically around $20, although they can go to $300.

I think its a bad design to use MCU as a signal generator. MCU is basically management unit that should be used to manage other devices. That's a whole point of being able to program MCUs.

In a way of an example I found these two signal generators that can be managed over I2C/SPI interface:

AD9833 Signal & Function Generator w. Programmable Amplifier / Vcc= 2.3-5.5V, f= 0-12.5 Mhz, acc: 50ppm, 0.1Hz / comms: SPI / ... about $10.00

AD9834 – DDS Signal Generator Sine/Triangle/Square/Sawtooth Wave Programmable / VCC= 2.3..5.5 V / f< 37.5 MHz / output: V< 0.6V, I< 3mA, P< 1.8mW / comm: SPI / ... approx. $20.0

So, both of these cheap devices can outperform your approach by a factor between 5 to 15 times.

Another thing, there is this Raspberry Pi 2 W with four 1 GHz cores. Pi 2 W has a ridiculously small footprint and it fit in with any experiment. So, theoretically, one can run 4 programs simultaneously.

 

[Nwakuche]

Great post. Thank you for writing this.

I would like to add that the route you suggested is not the only one. There are lots of ADCs & DACs on the market that can be managed through I2C or even better SPI interface. These devices can then produce waveform that you choose by setting only a few defining parameters over the interface and you can have several such devices on the interface chain. And these devices cost typically around $20, although they can go to $300.

I think its a bad design to use MCU as a signal generator. MCU is basically management unit that should be used to manage other devices. That's a whole point of being able to program MCUs.

In a way of an example I found these two signal generators that can be managed over I2C/SPI interface:

AD9833 Signal & Function Generator w. Programmable Amplifier / Vcc= 2.3-5.5V, f= 0-12.5 Mhz, acc: 50ppm, 0.1Hz / comms: SPI / ... about $10.00

AD9834 – DDS Signal Generator Sine/Triangle/Square/Sawtooth Wave Programmable / VCC= 2.3..5.5 V / f< 37.5 MHz / output: V< 0.6V, I< 3mA, P< 1.8mW / comm: SPI / ... approx. $20.0

So, both of these cheap devices can outperform your approach by a factor between 5 to 15 times.

Another thing, there is this Raspberry Pi 2 W with four 1 GHz cores. Pi 2 W has a ridiculously small footprint and it fit in with any experiment. So, theoretically, one can run 4 programs simultaneously.

Thanks for your reply however
AD9833 and AD9834 does not support SPWM. In-order to switch mosfet driver efficiently, we need need the sine wave equivalent which is SPWM i.e sinusoidal pulse width modulation.
Raspberry pi 2 w has only TWO hardware PWM channels while we need four independent channels. MCU is the best to be used in the MAGVID device as you can program the SPWM frequency up-to high frequencies provided you use the hardware pwm pins.

INFACT, MCU is highly necessary for the MAGVID related devices as you will come to know. You will need MCUs for power control, shutdown procedures both emergency and normal operation, navigational purposes, stabilization of vortex field.i.e when you are building a spacecraft based on the MAGVID principles.

 

[Nwakuche]

Thanks for your reply however
AD9833 and AD9834 does not support SPWM. In-order to switch mosfet driver efficiently, we need need the sine wave equivalent which is SPWM i.e sinusoidal pulse width modulation.
Raspberry pi 2 w has only TWO hardware PWM channels while we need four independent channels. MCU is the best to be used in the MAGVID device as you can program the SPWM frequency up-to high frequencies provided you use the hardware pwm pins.

INFACT, MCU is highly necessary for the MAGVID related devices as you will come to know. You will need MCUs for power control, shutdown procedures both emergency and normal operation, navigational purposes, stabilization of vortex field.i.e when you are building a spacecraft based on the MAGVID principles.

hardware PWM of MCU is like having a programmable muliple 555 timers with multiple input/output. Read about it and you will see the wisdom in my pathway.

 

[Dejan Corovic]

hardware PWM of MCU is like having a programmable muliple 555 timers with multiple input/output. Read about it and you will see the wisdom in my pathway.

Can you please explain ( or point me to the explanation ) why is SPWM needed.
As a matter of a fact, I never before had heard of SPWM signals. Really interesting.

 

[Nwakuche]

Can you please explain ( or point me to the explanation ) why is SPWM needed.
As a matter of a fact, I never before had heard of SPWM signals. Really interesting.

Good morning from my location.
High power amplifiers needed to amplify sine wave signals of such frequencies to used in the MAGVID related devices are relativly expensive and not power efficent (50% to 70%). To amplify weak signals from such boards as the AD9833 and AD9834, you will need a preamplifier and power amplifier or in one.

Bipolar transistors and Mosfets usually prefer to be fully on or fully off. In this operating conditions, they drop the least amount of voltage across their power pins and minimum amount of power is wasted. Sine wave signals force them to operate mostly in the linear region in which they are neither fully on or off so be prepared to dissipate a lot of wasted power if you want to follow this path. This would increase the odds of components failing if cooling system fails for any reasons.

I would use your path if i dont want to go through tge hassle of programming an MCU and i have enough money to spend on amplifiers and cooling system but i would not use it for any more than a MAGVID inverter for reliability reasons.

SPWM is sinusoidal pulse width modulation. Remember that the duty cycle of a square wave determines the aveeage voltage as read on a digital multimeter.i.e a square wave signal of 10v and 50% duty cycle gives an average voltage of 5v while that of 20% gives an average voltage of 2v. Remember that a sine wave amplitude (voltage) changes uniformly from zero to maximum back to zero over an half cycle so by changing the duty cycle of a high frequency square wave signal over multiple cycles, we can the sine wave equivalent of low frequency signal whose amplitude changes uniformly over the entire period of the signal.
This process is called sinusoidal pulse width modulation (SPWM) technique. You can now use an LC filter just like in pure sine wave inverters to convert the High power SPWM signal into an actual sine wave signal.

So you get the power saving and reliability benefits of using square waves while getting the High power sine wave signals you want.

that is that.

If you can recommend a reliable amplifier that is not expensive (not more than $30) then your method is preferable to the hassle of programming a MCU hardware PWM pins as the output power of all MAGVID related devices scales not only with rotating magnetic field strength but with its frequency of rotation and current MCUs have a limit ( few MHZs) on the frequency they can synthetize.

Thanks.i do enjoy these discussions as they simulate critical thinking on a lot of important issues.

 

[Dejan Corovic]

Good morning from my location.
High power amplifiers needed to amplify sine wave signals of such frequencies to used in the MAGVID related devices are relativly expensive and not power efficent (50% to 70%). To amplify weak signals from such boards as the AD9833 and AD9834, you will need a preamplifier and power amplifier or in one.

Bipolar transistors and Mosfets usually prefer to be fully on or fully off. In this operating conditions, they drop the least amount of voltage across their power pins and minimum amount of power is wasted. Sine wave signals force them to operate mostly in the linear region in which they are neither fully on or off so be prepared to dissipate a lot of wasted power if you want to follow this path. This would increase the odds of components failing if cooling system fails for any reasons.

I would use your path if i dont want to go through tge hassle of programming an MCU and i have enough money to spend on amplifiers and cooling system but i would not use it for any more than a MAGVID inverter for reliability reasons.

SPWM is sinusoidal pulse width modulation. Remember that the duty cycle of a square wave determines the aveeage voltage as read on a digital multimeter.i.e a square wave signal of 10v and 50% duty cycle gives an average voltage of 5v while that of 20% gives an average voltage of 2v. Remember that a sine wave amplitude (voltage) changes uniformly from zero to maximum back to zero over an half cycle so by changing the duty cycle of a high frequency square wave signal over multiple cycles, we can the sine wave equivalent of low frequency signal whose amplitude changes uniformly over the entire period of the signal.
This process is called sinusoidal pulse width modulation (SPWM) technique. You can now use an LC filter just like in pure sine wave inverters to convert the High power SPWM signal into an actual sine wave signal.

So you get the power saving and reliability benefits of using square waves while getting the High power sine wave signals you want.

that is that.

If you can recommend a reliable amplifier that is not expensive (not more than $30) then your method is preferable to the hassle of programming a MCU hardware PWM pins as the output power of all MAGVID related devices scales not only with rotating magnetic field strength but with its frequency of rotation and current MCUs have a limit ( few MHZs) on the frequency they can synthetize.

Thanks.i do enjoy these discussions as they simulate critical thinking on a lot of important issues.

Brilliant explanation.
Thank you for enlightenment.

 

[Dejan Corovic]

If you can recommend a reliable amplifier that is not expensive (not more than $30) then your method is preferable to the hassle of programming a MCU hardware PWM pins as the output power of all MAGVID related devices scales not only with rotating magnetic field strength but with its frequency of rotation and current MCUs have a limit ( few MHZs) on the frequency they can synthetize.

I think I've seen signal generating chips where desired signal can be reproduced from values stored in the memory of the chip ( EPROM ). Then one be able to calculate SPWM he wants and store it in EPROM.

But I don't know of any of the top of my head. If I find some I'll report back here.

 

[Dejan Corovic]

I understand a very important point that MOSFETs & transistors dissipate heat and really like working outside linear regions.

But one thing worries me slightly. Would these SPWM pulses slightly distort sinusoidal and create bumps in gaps. As well, rising and falling edges will produce ringing and noise. What are your thoughts on that?

Yet another thing might be that one doesn't need high power to "top up" MAGVID. High frequency might be enough. As an exaggerated example, if one wants to push in say 100 Jules of energy in one second, he can either push 2 Jules 50 times per second, or 0.001 Jules at 1,000,000 times per second ( 1 MHz ). So, in the second case each energy push is 2,000 smaller then in the first case. So, by using higher frequency one can avoid overheating, while supplying the same energy.

 

[Dejan Corovic]

I just had a quite fun idea.

Why don't we try to make x2 identical bagel coils and then try to ENTANGLE them !

would that be possible?

 

[Nwakuche]

I understand a very important point that MOSFETs & transistors dissipate heat and really like working outside linear regions.

But one thing worries me slightly. Would these SPWM pulses slightly distort sinusoidal and create bumps in gaps. As well, rising and falling edges will produce ringing and noise. What are your thoughts on that?

Yet another thing might be that one doesn't need high power to "top up" MAGVID. High frequency might be enough. As an exaggerated example, if one wants to push in say 100 Jules of energy in one second, he can either push 2 Jules 50 times per second, or 0.001 Jules at 1,000,000 times per second ( 1 MHz ). So, in the second case each energy push is 2,000 smaller then in the first case. So, by using higher frequency one can avoid overheating, while supplying the same energy.

Sorry for the delay in reply, i fell asleep while in front of my laptop computer. Higher frequency is only beneficial as to the end results of the rotating magnetic field system. As you know, for the application of the MAGVID principles in-order to create a "SHIFT in Space and Time" ( where the central magnetic field is needed ), there is a minimum frequency required in order for the vortex created from the RMF ( rotating magnetic field ) to become self sustaining.

For Mosfets and Bipolar-transistors, losses increases with increase in operating frequency and it even gets worse when they are operated in their linear region. If i am going to build a MAGVID charging device for alchemy or spacecraft purposes, i would simply choose a maximum frquency that i can safety generate without compromising my electronic system ( minimum frequency relates to the Time it takes light to travel around the circumference of the space enclosed by the RMF and the relaxation Time of a electrical discharge in air ) and focus on increasing the magnetic field strength.