“BitLife Astronaut Scan” Have you ever fantasized about traveling through space? BitLife allows you to turn this fantasy into reality. In this engaging simulator game, you can evolve from an everyday character to a celebrated astronaut. However, to accomplish this goal, you must navigate many challenging decisions. In this guide, I will outline how you can become a successful astronaut in BitLife.
Requirements to Become an Astronaut in BitLife
To maximize your chances of becoming an astronaut in BitLife, focus on the following critical areas:
Education:
To enhance your qualifications, you should pursue an advanced degree, such as a master’s or Ph.D., along with a degree in STEM (science, technology, engineering, or mathematics) subjects.
Skills:
Hone your skills in areas like technology, engineering, and accounting. Also, consider engaging in extracurricular activities that are related to space exploration.
Physical fitness:
Prioritize your physical fitness throughout all stages of life. Regularly participate in vigorous physical activities and exercises to improve your heart and body strength.
Luck:
Luck is an essential component in becoming an astronaut in BitLife. Alongside solid education, good judgment, and diligent work, a bit of luck is also significant.
Table of Scan Frequencies of All Planets in BitLife
| Planet/Area | Frequency Range | Observations/Findings |
|---|---|---|
| Sun | 0 – 9 GHz | A cluster of sunspots forming. |
| Mercury | 10 – 19 GHz | A pulsing radio signal from Mercury. A rapid radio signal from Mercury. |
| Venus | 20 – 29 GHz | Disruption in the planet’s energy. |
| Mars | 30 – 39 GHz | A strange shift in Mars’ magnetic field. A steady radio signal from Mars’ ionosphere. The sound of ‘Life On Mars’ playing near the Gale Crater. |
| Jupiter | 40 – 49 GHz | The sound of Europa’s ocean leaking into space. Radio waves bouncing between Jupiter and Callisto. A volcanic eruption on Io. A rhythmic radio frequency emanating from Callisto. |
| Saturn | 50 – 59 GHz | A peculiar radio signal originating from Iapetus. Radio emissions from Enceladus interacting with Saturn’s magnetosphere. |
| Uranus | 69 GHz | The presence of an unidentified ring around Uranus. |
| Neptune | 70 – 80 GHz | Synchrotron radiation emitted by Neptune’s Dark Spot 2. Synchrotron radiation emitted by Neptune’s Great Dark Spot. A volcanic eruption on Triton. |
| Deep Space | 80 – 100 GHz | A black hole consuming a probe. The sound of two neutron stars colliding. A radio wave from a distant galaxy. A black hole engulfing a nebula. A snippet of Rick Astley’s ‘Never Gonna Give You Up’ reflecting off a distant planet. A snippet of the ‘Power Rangers’ theme song echoing from a far-off planet. Some funky alien beats. A white hole erupting in deep space. A desperate radio signal from Mercury. |
| Pluto | Random frequencies between 70-100 GHz | The fluttering of a meteor shower dusting the planet. |
