The relay
The relay consist of a boron conducting long joystick like part imbedded inside a strongly elastic material, so also the ball is imbedded, and It also shouldn’t rip when stretched around the ball and when stretched behind the ball. The ball should also be small like the stick.
It’s like a conductor inside a strongly elastic condom, which is stretched to contract around the conductor by resilience with a hole, while the conductor extends outside the hole to connect to the circuit.
The sideways part exits, so the end of the sideways part prevents it from turning further.
It looks better when the measurements are right, so when the whole switch is tiny, and we could shield it of with walls in the third dimension.
We avoid destroying stuff on our planet when we use a relay, because we can control the direction.
Continuity Equation
1/divergence = depth:
(ΔZ / Δ ) 
= W ∝ J
Δdepth / Δtexture density =
Δprojection distance ∝ texture
W = (Δdistance / Δtexture density) * J = W = depth
The charge density is analogous tot he texture density.
It is the projection distance, Which is why the change in texture density for the depth The depth has a minus before itself, and that makes W the same for both directions of the texture change (getting denser or wider).
The texture density is analogous to the charge density, so our brain can determine W, which is actually the eye distance, and our brain can thus determine depth by the continuity + equation, but not solely by one texture, because W (projection distance from graphics, which is actually the eye distance) isn’t known for X/W, Y/W, and Z/W in the texture formulas from the U & V coordinates.
We can also use a photometer by a 360 degree telescope at the direction in which we travel, but not exactly at the center, although close to it below:
* J = W = distance
We shine an electromagnetic inducting signal at the superconducting electromagnet, so bypassing the switch for the relay from the photometer, and the relativistic displacement is faster than light, because the spaceship moves towards the light, so the incrincreased time dilation waves spacetime to make the distance shorter.
We would have to determine the orbits of the planets though, while noticing that our projection is recieved with C, so we cloak the photometer in a shadow by glass alumina shutters. The solar irradiance has been shown to vary less than 0,2% in the last 400 years, and the deviation of the magnificationfactor of the outer planet’s radius to it’s sun by mass is the deviation of the magnificationfactor of the sun’s mass.
We solve the last part with astronomy by using the continiuty equation + to determine W along with the orbits, and W/C = elapsed time of the orbits,
while it should stop automatically by a computer, which means the braking distance is set before we go.
We use the alumina glass shutter to block neutrinos & antineutrinos.
The distance from the shutter to the photometer is limited by the angle of incidence by the size of the shutter, although noticing that it is round and that we don’t aprouch the suns too close.
The detector and the superconducting electromagnet and overall everything that moves relative to the light go to the future by the time dilation from the photons for the surrounding bend, so we need a detector whose phase velocity doesn’t depend on time, because the velocity already is a contraction of time and space.
Annihilating the nucleus (again like smashing rocks into pieces) to create neutrinos and antineutrinos is limited by the amount of particles, and is overall unpractical.
Romoeja (spaceship/ drone)
We could perhaps warp out of our atmosphere with this streamlined mainframe.
The spirebold is above:
It is overall streamlined and made of osmium, but it has two fused osmium glass rings for the spaceship where they spin normally (hoping that the voltblazers don’t destroy it) and at gas discharge lamps made from osmium glass, and I figured that rotating it in two different directions isn’t only more efficient by reaching further with normal force, but it just looks cooler. It keeps rotating when the rotational energy equals the resistance. We could bend and fuse the spire on the spirebold, instead of carving. The spirebold with a hollow inside is of course molded in halves.
We rotate the malves to eachother, so it creates a stable position, and we end the spire to keep it spinning normally in the center. As seen the shape and spire must be symmetric for stabilization. The malve would move partly vertical, but the extending spire from the spireblade inhibits the hollow circles from the malve, because we can’t move a nut as example up or down without rotating.
The spirebold is partly open above for a hatch, because it must close perfectly, due to the vacuum.
The malves look like this as mainframe:
The malves have a transparant streamlined osmium glass ring at the top where they spin normally (hoping that the voltblazers don’t destroy it), and they have gas-discharge lamps made from osmium glass. The osmium glass is fused. They are overall streamlined, so the gas-discharge lamps fits into the malve’s hollow slith, and they are also made of osmium for the rest of the spaceship, due to the nihil, but present resistance for post-relativistic speeds. We could spray coatings of antioxidants against oxidation from osmium inside, because it is otherwise toxic.
The supermagnet is fused into the bottom of the malves, and the malves are fused in pieces, and the malves don’t consist of negative oxidation states. We heat it at the bottom with surrounding red (mainly O2) and infrared light (mainly C02 and nitrogen) to create thermal at the bottom. The malves are incited by the spinning supermagnet.
The bottom malve is closed underneath with a gap in the center above and beneath for a circular window.
We amberize the 3-phase voltage installation to the bottom of the malve, because we amberize an isolating layer at the bottom of the malves, while we amberize the 3-phase voltage installation to the isolation, although the 3 phase installation shouldn’t stick out, due to the resistance. As known the polarity from the 3-phase voltage shifts from positive to negative and vice versa for energy efficiency. We use the resin from the Maracta nut tree’s resin to stick it. The osmium core from the electromagnets must be a beam and not a cylinder to stick it, while the surface from the core of the electromagnet doesn’t have a too big height.
The spire and shape of the aircraft makes the radius just as small as in the bottom for the center, which causes a higher centrifugal force combined with a higher velocity for more centrifugal force in thermal to rise in altitude.
We rotate a supermagnet with an example of the 3-phase voltage installation, while the point of engagement is not in the center, but at the end of the supermagnet for more centrifugal force and it’s even stronger when the 3-phase installation incites the supermagnet.
The deviating ones from both 3-phase voltage installations should be on eachothers opposite side, while the osmium packages of the reducing and oxidizing agents could be between and behind the two other electromagnets for each 3-phase voltage.
The osmium wires could be camouflaged in a ochre like colour with a varying texture. I guess by coloring the metal with a laser somehow. The same colour as the osmium layer, which covers the isolating layer to prevent shocking:
We amberize rings of gas-discharge lamps with osmium glass without a ballast in pieces for red and infrared light almost at the bottom with a high voltage and with the long life batteries.
Again: 
P = E (without time)
To generate the frequency, and I think that a higher amplitude of the voltage creates a higher amplitude of the photons, and we use a LDR dimmer to descent.
We use the absorption wavelengths from the absorption spectra, so the wavelength depends on the abundant substances in the atmosphere of the planet or the Higgs bosons for moons, which is why we could use more than two gas-discharge lamps.
Although hollow the mixture between the flying disc and the air hockey puck effect (higher content compared to surface) results in less friction together.
We walk into the spaceship from the magnetic hatch at the top or bottom.
The romoeja lifts due to thermal, because thermal and centrifugal force along with the normal force from spinning in two different directions creates slanting up vectors.
It captures more air for lift, because the centrifugal force reaches further.
The romoeja can have windows as spaceship when it is big enough and we include: photometers and a telescope. It has windows between the spires and a circular window above and a circular window beneath in the center.
It needs four voltblazers as drone between the spires and the four cameras (for a drone) by a transformer:
neglecting 0 turns, but we don’t make a coil around the primary electromagnet, while the Doppler effect only decreases the frequency even further when the drone moves away from us, while the sound is send in the opposite direction in which it moves. The conus must be made of osmium along with some parts of the speaker.