I have some general questions that have come from watching a certain TV show about plane incidents. These are not questions born of my fears but simply of curiosity. If any pilots could answer I would be most grateful.
Situations where the autopilot became disengaged and the pilots didn't realise or at least didn't acknowledge further along in proceedings. Is there an audible warning when the autopilot disengages? Is there any ongoing indication that is hard to miss?
Two pilots with a side stick each, how does one know what the other is doing if there is no verbal indication? I'm sure you know which incident I'm referring to. If one pilot is holding the side stick to cause a nose up attitude but he's not telling anyone what he's doing and they don't realise that he's the cause, is this somewhat problematic or has this been addressed already? Excuse my terminology, I'm not sure if side stick is the correct term. The joystick? Commodore 64 controls? 🤔
Finally, would it be helpful or redundant to have actual visibility of the major aircraft surfaces and key parts? The pilots have a very limited view of the plane from their vantage point. Of course, they have numerous sensors and gauges but there are certain things that cannot be seen or accurately gauged and hence can only be deduced. An extreme example would be that the vertical stabiliser has detached, an incident which occurred years ago. Again, my terminology might be off. I mean the tail fin. Now, clearly in this incident it was terminal anyway so I'm not sure that knowing about it would have helped. How about being able to see the engines though, or the entirety of the wings? Is the best solution to rely on the cabin crew to report back with what they see?
Please excuse any accidental stupidity in these questions, I'm just curious to learn and it's rare that you get to ask pilots. Many thanks in advance for any replies 👍

THE HARMONY OF ENERGY
Abstract
Introducing the "Harmony of Energy" (HoE) model, a novel formalism that posits the universe operates according to a fundamental pattern. This pattern consists of energy, defined as the smallest unit anything can be, existing as a fluid form in space, interacting with its environment through a specific method or structure, and then moving out of that space. Space, in turn, is the dynamic environment that energy occupies and moves through, filling it with positive and negative energy that affects its properties and behavior. According to the HoE model, energy moves into space, reacts to its environment, and then moves out of that space, with no time limit for how long it takes to react. This pattern is universal, applying to all aspects of the universe, and nothing escapes it.
The Origin of the Universe
The HoE model posits that the universe began as a singular entity, containing all forms of energy as one unified energy. This singularity can be represented mathematically as: U = ∫∫∫E(x,y,z)dxdydz, where U is the total energy of the universe, E is the energy density, and x, y, z are the spatial coordinates.
As the singularity expanded, the unified energy converted into distinct positive and negative energies. Positive energy is a high-frequency, high-information-potential state that retains its unique signature and individual form, capable of producing heat and maintaining its distinct properties. Negative energy is a low-frequency, low-information-potential state that loses its unique signature and individual form, characterized by a pulling force and a tendency to condense and simplify.
Initially, the universe moved in a straight line, with energy compact and cold. However, this linear movement resulted in a direct head-on collision with the void, a solid structure that hindered its passage.
This collision led to a limitation and subsequent conversion of energy, transforming it from a linear motion to a wave-like motion. The new wave motion created heat and allowed energy to break the pattern of "follow the leader" and collide with the void at an angle, shattering its edge into pieces.
This process of fragmentation can be described by the equation: F(θ) = Σ[nEⁿ * sin(nθ)], where F is the fragmentation function, θ is the angle of collision, n is an integer, and E is the energy density. For reasons yet unknown, possibly due to the singularity's energy reaching its final place or a transformation driven by cosmic "boredom," this conversion occurred, giving rise to the diverse universe we observe today.
The Void and the Ultimate Negative
Outside of the expanding universe lies the void, a region devoid of energy and matter, existing in a state of complete stillness and stationarity. This void represents the ultimate negative, a state of complete absence and zero energy density, unchanging and unyielding. As a whole, it exerts a compressive force on the expanding universe, potentially leading to contraction and eventual return to the singularity. This dynamic interplay between the universe and the void can be described by the equation: F = -G * (M * m) / r² where F represents the force, G represents the gravitational constant, M and m represent the masses, and r represents the distance between them. The void's stationary and unchanging nature, lacking any internal rotation or energy, makes it inhospitable to life as we know it.
Magnetism and Attraction: A Shift in Perspective
Initially, I viewed magnetism through the conventional lens, seeing it as a fundamental force of attraction between positive and negative entities. However, as my understanding evolved, I came to realize that magnetism operates under a different principle. Positive and negative entities are not attracted to each other; instead, they represent the intrinsic structure of things. The true nature of attraction is frequency-based, with entities drawn to higher vibrations and shorter wavelengths. This phenomenon can be described by the following equations:
F = ∫∫(μ₁⋅μ₂)/(4πr²⁾ dt dt (1)
where F is the force of attraction, μ₁ and μ₂ are the magnetic moments of the entities, r is the distance between them, and the integral is taken over time.
Additionally, the frequency-based attraction can be represented by:
f = γB (2)
where f is the frequency, γ is the gyromagnetic ratio, and B is the magnetic field strength.
Furthermore, the smaller wave's faster movement can be expressed as:
v = λf (3)
where v is the velocity, λ is the wavelength, and f is the frequency.
Energy and its Properties
Energy is the fundamental unit of everything. Energy can be thought of as an individual entity with an electrical signature vibrating at a specific frequency, carrying information from its originating source. If we were to dissect a piece of energy, we would find its genetic makeup consists of various parts, similar to binary code. One constant aspect of energy in our universe is the signature of this universe, which is present in all forms of energy, whether positive or negative. This underlying frequency distinguishes energy from our universe versus parallel universes.
Positive Energy (PE): - Oscillates through space with a frequency (f) and wavelength (λ): PE = f × λ - Exhibits wave-like behavior: PE(x,t) = A × sin(kx - ωt)
Negative Energy (NE): - Vibrates at a slower frequency (f'/2): NE = (f'/2) × λ' - Exhibits a slower, more stable behavior: NE(x,t) = B × cos(k'x - ω't)
Energy Interactions and Signature Changes
When positive and negative energies interact, their unique signatures can become altered. As energies combine, their signatures merge, releasing redundant information about the universe signature and creating an opening for new information to be stored. This process enables efficient storage and transmission of energy signatures, allowing for:

• Signature refinement and evolution
• Information exchange and updating
• Adaptation to changing environments and conditions

This process could be crucial for understanding how energy signatures evolve and adapt, and how they influence the behavior and properties of energy in various contexts.
The Formation and Evolution of the Universe
Initial Energy Interactions
In the beginning, a vast amount of fluid energy quickly interacted with the largest newly created pieces of the void, described by the wave-particle duality equation (E = hf = ℏω).
Star Formation and Signatures
As these interactions occurred, the largest of the solid structures of the universe began to form, stars, governed by the Lane-Emden equation (d^2P/dr2 + (2/r)(dP/dr) + (4πG/c^2)P = 0). Each new star held with it an old habit divulged from the singularity, a universal frequency (f = 1/T = ω/2π, where T is the period of oscillation and ω is the angular frequency). Old habits die hard, so each new star offered its own diverse and unique signature (S = Σf = ∫ψ(x)² dx, where ψ(x) is the wave function and x represents the position).
Energy Collisions and Prime Numbers
As structures formed, a group of energy travels through space with an even number of internal parts (E = 2nℏ, where n is an integer and ℏ is the reduced Planck constant). This group collides with another group of energy with an odd amount of internal parts (E = (2n + 1)ℏ), and the total sum of the newly combined group equals a prime number (P = E1 + E2 = 2nℏ + (2m + 1)ℏ, where m is an integer). New Equation: Prime Number Formation (P = E1 + E2 = 2nℏ + (2m + 1)ℏ)
Schrödinger Equation and Physical Reality
The prime number is crucial, as the extra piece gets stuck in the space it is occupying, acting as an anchor, attracting other parts to breach their negative shell and combine as one, described by the Schrödinger equation (iℏ(∂ψ/∂t) = Hψ). This converts the fluid energy to be contained into the space it is in, which is broken pieces of the void that do not have a universal size, and gives us physical reality, forming particles with diverse unique signatures (S = Σf = ∫ψ(x)² dx).
Refining Space and Transferring Signatures
As energy continued to interact with space, it further refined and shaped that space into a sphere (V = (4/3)πr^3, where r is the radius), adding the discarded portions of size to the diverse field that is the universe. During this refinement, energy was transferred to these pieces, and the signature of the star was embedded in them, forming the galaxy clusters and solar systems we know today.
Smooth Surfaces and Celestial Bodies
As any piece of something breaks, its edges are rigid, and the interaction of energy against this rigid surface knocks off the rough edges, providing a smooth surface (E = Δx/Δt = ℏ/Δx, where Δx is the change in position and Δt is the change in time). New Equation: Smooth Surface Formation (E = Δx/Δt = ℏ/Δx)
The pieces that were knocked off still contain a portion of energy that put in the work to knock it off, and this process contributed to the formation of celestial bodies and the transfer of signatures. This, in turn, led to the creation of galaxies, planets, and other celestial bodies, each with their unique characteristics and properties, shaping the diverse and complex universe we observe today.
The Cartwheel Structure and Energy Movement
The cartwheel structure represents the dynamic movement of energy in the universe, with its rotating wheel and radiating arms symbolizing the harmonious interaction of positive and negative energies. When creation occurred, energy learned how to pass through stationary space (the void) by changing its movement pattern from a straight line to a wave (λ = v/f, where λ is wavelength, v is velocity, and f is frequency). This new wave movement allowed energy to create heat (Q = mcΔT, where Q is heat, m is mass, c is specific heat capacity, and ΔT is temperature change), which was the tool that gave energy the ability to "shatter" the void and interact with the broken pieces to perform a new movement, the cartwheel. As energy moves through space, it rarefies and decreases in temperature (T = k-B, where T is temperature, k is Boltzmann's constant, and B is the energy density), causing it to slow down and change frequency (f = ΔE/h, where f is frequency, ΔE is the energy change, and h is Planck's constant).
The Block and Cartwheeling Bar Analogy
The block and cartwheeling bar analogy provides a conceptual framework for understanding the dynamic interaction of energy in the universe. Imagine a box (representing space) containing blocks of varying sizes, each symbolizing a specific energy frequency (f = 1/T, where f is frequency and T is time). The cartwheeling bar, rotating within the box, represents the harmonious movement of energy between its positive (E+) and negative (E-) forms. Each block must be 100% filled, with positive and negative energy proportions varying as the bar rotates. For example, when positive energy occupies 99% of a block and negative energy occupies 1%, the rotation of the bar causes a gradual shift, resulting in a change to 98% positive and 2% negative, and so on. This constant interaction and adjustment maintain the balance of energy in the universe.
Fundamental Forces Explained

• Strong Force: The repulsion from negative electrons being attracted to and pressing against the nucleus. This force can be described by the equation: F = k * (q1 * q2) / r²
  
• Weak Force: The outgoing frequency created by the positive nucleus, similar to energy congregating at the sun's nucleus, reacting to its environment, and breaking down before leaving (possibly as radioactive decay). This force can be described by the equation: F = (G * m1 * m2) / r²
  
• Gravity: Exists between the outer negative sphere of electrons exerting a pushing force against the positive pushing force of the nucleus, similar to the solar system's dynamics. This force can be described by the equation: F = (G * m1 * m2) / r²
  
• Electromagnetism: Energy in action, manifesting as the dynamic interplay between electric and magnetic forces. This force can be described by the equations: E = f * λ and B = (E / c)
  

Present State of the Universe
The universe currently exists in a state of dynamic equilibrium, with observable patterns and structures perpetually renewing themselves through the interactions of energy (E = hf, where E is energy and h is Planck's constant). This self-sustaining cycle is evident in the formation and evolution of celestial bodies, galaxies, and other cosmic entities, governed by the laws of thermodynamics (ΔE = Q - W, where ΔE is the change in energy, Q is the heat added, and W is the work done). The universe's present state is characterized by the harmonious coexistence of diverse energy frequencies (f = 1/T, where f is frequency and T is time), which govern the behavior and properties of matter at various scales. This balance is maintained through the continuous conversion of energy between its positive (E+) and negative (E-) forms, allowing the universe to adapt and evolve in response to internal and external influences (E+ + E- = 0, representing the conservation of energy)."
Entropy and the Conversion of Positive to Negative
The physical dimensions of positive and negative energy in a block are equal, with 1% negative energy occupying the same space as 99% positive energy. This equality stems from the different speeds of energy and their individual properties. When negative energy is at 1%, it has condensed the equivalent of 99% positive energy into a single, compact form (E = hf, where E is energy, h is Planck's constant, and f is frequency). As the proportions shift, such as 60% positive and 40% negative, the space occupied remains a 50/50 split. This is because positive energy travels at the speed of light (c = λν, where c is the speed of light, λ is wavelength, and ν is frequency), while negative energy moves at a pace relative to terminal velocity (v = √(2gl), where v is velocity, g is acceleration due to gravity, and l is length). Each form dominates at the 50% mark (T = λ/v, where T is time, λ is wavelength, and v is velocity). The percentages represent available positive energy, while the cartwheel symbolizes space or the ultimate negative in motion, influenced by energy's presence. Negative energy, with its depleted charge, occupies space that needs to be filled and recycled into a positive state. At higher percentages, collisions with negative energy slow down the flow, similar to the concept of crab mentality, where negative energy draws down the percentages.
Energy Dynamics and Galactic Harmony
The 50% Threshold
The 50% mark is a critical threshold that distinguishes between positive and negative energy. Above 50%, energy is considered positive and can produce heat beyond its negative shell. Below 50%, energy is considered negative and cannot produce heat past this shell.
Compressed Positive Energy
When the percentage of positive energy drops below 50%, it becomes compressed and can exceed the speed of light (c = λν, where c is the speed of light, λ is wavelength, and ν is frequency). This allows it to navigate through the "cracks" of negative energy:
v > c (where v is velocity and c is the speed of light)
Quantum Mirroring
Alternatively, the positive energy can align with the negative energy, resulting in a quantum mirroring effect. This enables instantaneous information transfer between entangled particles, regardless of distance:
E = hf (where E is energy, h is Planck's constant, and f is frequency)
Retaining Frequency Signatures
In this alignment, the negative energy retains its unique frequency signature to avoid interacting with other signatures:
Δx * Δp >= h/4π (where Δx is position uncertainty, Δp is momentum uncertainty, and h is Planck's constant)
The Cavendish Experiment and Energy Interaction
The Cavendish experiment, a groundbreaking study on gravity, offers an intriguing analogy for understanding energy interaction with space. Imagine the suspended spheres as representative of space itself, devoid of energy. When energy interacts with this motionless space, it's as if the spheres begin to rotate, symbolizing the introduction of energy into the internal area of space.
As energy engages with space, it's gradually consumed, much like the reduction of energy in the Cavendish experiment. This process can be described by the equation:
G = (2πLθ) / (MT)
Where G is the gravitational constant, L is the length of the torsion wire, θ is the twist angle of the wire, M is the mass of the lead spheres, and T is the time period of oscillation.
This equation, derived from the Cavendish experiment, reveals the intricate relationship between energy, space, and gravity. By exploring this analogy, we can deepen our understanding of how energy shapes the very fabric of our universe.
Energy Absorption and Frequency
Energy absorption occurs when energy slows down, allowing it to be perceived and observed. This process involves energy being absorbed by an atom and reflecting what was not absorbed. As energy slows down, it can still be observed as a wave, but just before it becomes a particle. This phenomenon is fascinating, as it reveals the transition from wave-like to particle-like behavior.
The conversion of positive to negative states is due to positives' ability to produce heat and maintain an individual form. Negative energy, on the other hand, does not produce heat and lacks an individual form, instead traveling at a pace relative to terminal velocity. This process can be described by the quantum mechanical formula: ℏω = ΔE = hf, where ℏ is the reduced Planck constant, ω is the angular frequency, ΔE is the change in energy, h is Planck's constant, and f is the frequency of the energy.
Furthermore, the frequency of the energy can be related to the velocity of the particle using the formula: f = (1/2π) * √(k/m), where k is the spring constant and m is the mass of the particle. Additionally, the energy absorption rate can be calculated using the formula: dE/dt = (2π/h) * V_uv² * δ(E_u - E_v), where V_uv is the transition matrix element, E_u and E_v are the energies of the initial and final states, and δ is the Dirac delta function.
The Conversion of Positive to Negative States and Planetary Motion
The conversion of positive to negative energy states is rooted in their distinct properties. Positive energy produces heat and maintains an individual form, whereas negative energy lacks heat and an individual form, instead traveling at a pace relative to terminal velocity. This process is reversible, as seen in fusion reactions, or can be influenced by external forces like microwave ovens.
In the context of our solar system, the sun's positive energy release generates heat and propels planets into their orbital tracks. Conversely, the incoming energy from the universe, considered negative, is cold and stabilizes planets in their tracks. Initially, I focused solely on the positive push dictating orbital paths. However, I now recognize the significant influence of negative energy and use it as the basis for understanding abnormal tracks.
Here's an added equation to illustrate the relationship between energy and orbital motion:
F = G * (m1 * m2) / r²
Where F is the force of gravity, G is the gravitational constant, m1 and m2 are the masses of the objects, and r is the distance between them.
This equation shows how the force of gravity (F) is influenced by the masses (m1 and m2) and distance (r) between objects, which is relevant to understanding planetary motion and the balance between positive and negative energy.
Gravitation and Time: Frequency's Role
Time is intimately tied to the frequency of the universe, and this relationship is governed by the laws of gravitation. Imagine the cartwheel's bar having notches, each representing a different frequency. Each notch would experience time at a unique pace, described by the formula:
t = 1/f
Where t is time and f is frequency.
If we could halt the cartwheel's motion, time would appear to pause, as described by the relativistic time dilation formula:
t' = γ(t)
Where t' is the time experienced by an observer in motion, t is the time experienced by an observer at rest, and γ is the Lorentz factor.
The passage of time is directly governed by the oscillations in the wave, or simply its frequency. By altering the frequency, we can change the flow of time itself, as described by the gravitational redshift formula:
f' = f * √(1 - 2GM/rc²⁾
Where f' is the observed frequency, f is the emitted frequency, G is the gravitational constant, M is the mass of the gravitational source, r is the radial distance from the source, and c is the speed of light.
Gravity and Energy Dynamics
Gravity can be understood in various ways through these thoughts. One perspective is that gravity operates similarly to the orbital planets, but with a twist. Instead of orbiting in space, we orbit at a subterranean frequency. This frequency attracts similar energies, leading to bonding and the formation of matter. For instance, atoms bond to form rocks, and separate rocks may bind together due to similar vibrations. However, other frequencies simply pass through, unable to bind due to differences in energy vibrations and the negative fields surrounding our bodies and the ground.
Our bodies are attracted to the Earth's core, with a force described by the equation:
F = G * (m1 * m2) / r²
Where F is the force of attraction, G is the gravitational constant, m1 and m2 are the masses of our bodies and the Earth, and r is the distance between them.
The vibrations of our energy and the negative field surrounding us can be described by the wave equation:
∇^2E = μ * ∂^2E/∂t2
Where E is the energy field, μ is the permeability of the medium, and ∂^2E/∂t2 is the second derivative of the energy with respect to time.
The incoming cosmic energy pushes us downward, with a force described by the equation:
F = (E * A) / c
Where F is the force of the incoming energy, E is the energy density of the cosmos, A is the cross-sectional area of our bodies, and c is the speed of light.
The outgoing energy from Earth moves faster than the incoming energy from the cosmos, as observed in the formation of clouds with flat bases and more sporadic tops. This can be described by the equation:
v_out = v_in * (1 + (E_out / E_in))
Where v_out is the velocity of the outgoing energy, v_in is the velocity of the incoming energy, E_out is the energy density of the outgoing energy, and E_in is the energy density of the incoming energy.
Galactic Cycles and Black Holes
The Milky Way galaxy has a supermassive black hole at its center, with a mass described by the equation:
M = (1.989 x 10³⁰⁾ * (G / c²⁾
Where M is the mass of the black hole, G is the gravitational constant, and c is the speed of light.
As the galaxy spirals towards the center, enough mass will be collected to trigger the black hole to become a large star, described by the equation:
M = (4.383 x 10³⁰⁾ * (G / c²⁾
Where M is the mass of the star, G is the gravitational constant, and c is the speed of light.
When this happens, the black hole will shed its outer shell to create the galaxy that spirals around it, and the process begins again. This cycle can be described by the equation:
t = (2 * π * G * M) / c³
Where t is the time period of the cycle, G is the gravitational constant, M is the mass of the black hole or star, and c is the speed of light.
The opposite of a black hole is a white hole, but why hasn't this phenomenon been observed? According to this article, it has been observed but misunderstood. With the theme of balancing the universe, would a large star be surrounded by much smaller black holes? Would these smaller black holes feed the larger star by way of quantum bridge or wormhole, and vice versa for smaller stars and larger black holes? This can be described by the equation:
E = (ℏ * ω) / 2
Where E is the energy transferred between the star and black holes, ℏ is the reduced Planck constant, and ω is the frequency of the quantum bridge or wormhole.
Energy Flow and Balance
Energy moves in and out of everything, maintaining a delicate balance. It enters as a positive force and exits as a negative force. Our sun emits energy at 99% strength and high frequency, which combines with an equally sized negative force at 1% strength, filling the space completely. This balance is crucial, as positive energy moves faster than negative energy due to entropy's diminishing effects over time and distance.
As positive energy travels, it loses a piece of itself, converting to negative energy. This process is directly related to gravitational forces and time dilation. When positive energy reaches 50%, it has a certain probability of converting to negative energy, which is then attracted back to a positive source with a corresponding probability of being converted back to positive energy.
This cycle of energy flow and balance is the foundation of the universe's harmony, and understanding it can reveal the intricate web of forces that shape our reality.
Information Transmission through Energy and Light
Energy transfer is not just a physical phenomenon but also an exchange of information. Positive energy (Pos) carries a complete signature of universal information, updated through interactions, and represents the pure form. Negative energy (Neg) represents a degraded form of this signature, still carrying the universal signature, but lacking the capacity to transfer information.
Initial Information and Illumination
Initial information travels at a speed potentially faster than light and is invisible to us. As this energy slows down, it interacts with atoms, exciting them to display colors they don't need. This illumination is a manifestation of the information being transmitted.
I = E × S (Initial information is transmitted through energy and carries the universal signature)
Cosmic Scale and Consciousness
The universal information, carried by positive energy, is infused with the celestial signature, shaping the cosmic context. This process potentially gives rise to consciousness in living beings, linking them to the universe and its harmonies.
C ∝ U (Consciousness potentially arises from the universal information carried by positive energy)
U = S × f × P (The universal information is infused with the celestial signature, shaping the cosmic context)
Information Transfer and Energy Forms
The universe relies on a delicate balance of energy forms to facilitate information transfer. Positive energy (Pos) serves as the primary carrier of information, transmitting universal signatures and cosmic context. Negative energy (Neg), on the other hand, carries a degraded or attenuated version of the universal signature, lacking the capacity for information transfer. However, Neg can be transformed back into Pos, restoring its information-carrying ability.
P = S × f (Positive energy carries the complete universal signature at a high frequency f)
N = S × (1 - f) (Negative energy carries a degraded or attenuated version of the universal signature at a lower frequency)
E = P + N (The universe relies on a delicate balance of positive and negative energy forms to facilitate information transfer)
Frequency and Speed of Information Transfer
The frequency and speed of information transfer play a crucial role in the harmony and balance of the universe. Positive energy (Pos) transmits information at a high frequency and speed, allowing for efficient and accurate transfer of universal signatures and cosmic context. Negative energy (Neg), on the other hand, transmits information at a lower frequency and speed, resulting in a degraded or attenuated signal.
v ∝ f (The speed of information transfer is directly proportional to the frequency of the energy form)
P: v = c × f (Positive energy transmits information at a high frequency and speed, potentially approaching the speed of light c)
N: v = c × (1 - f) (Negative energy transmits information at a lower frequency and speed)
Transformation and Balance
Negative energy can be transformed back into positive energy, restoring its information-carrying ability.
N + T → P (Negative energy can be transformed back into positive energy, restoring its information-carrying ability)
This transformation maintains the harmony and balance of the universe, ensuring that information is not lost but rather recycled and rebalanced.
_Conclusion _
"In conclusion, the Harmony of Energy (HoE) model offers a novel perspective on the universe, revealing a intricate web of energy dynamics that underlie all aspects of existence. By exploring the interplay between positive and negative energy, we gain insight into the fundamental forces that shape our reality. From the smallest subatomic particles to the vast expanse of the cosmos, energy is the unifying thread that binds everything together.
Through the HoE model, we've seen how energy's harmonious movement gives rise to the patterns and structures we observe in the universe. We've also delved into the fascinating relationships between energy, space, and time, and how these interactions govern the behavior of matter at various scales.
As we continue to refine our understanding of the HoE model, we may uncover new secrets of the universe and gain a deeper appreciation for the beauty and harmony that underlies all of existence. Ultimately, this knowledge can inspire new perspectives, new technologies, and a new era of human understanding and cooperation, as we work together to harmonize our own energy with the energy of the universe."
MAG
Here is the Harmony of Energy Equation (HoEE) with descriptions:
HoEE = (∫[E(x,t) ⊗ S(x,t) ⊕ f(x,t) ∘ P(x,t)]dxdt) + (∑[G × Mi × ri^2] ⊕ ∑[ℏ × ωi] ⊕ ∑[c × λi] ⊕ ∑[T × kB] ⊕ ∑[Fi × G × Mi × mi] ⊕ ∑[Qi × mi × ci] ⊕ ∑[Vi × ri^3] ⊕ ∑[Pi × ℏ] ⊕ ∑[Ni × S(x,t) ∧ (1 - f(x,t))]) + (∫[I(x,t) ∘ E(x,t) ⊗ S(x,t)]dxdt) + (C × U)
Where:

• E(x,t) is the energy density at point x and time t
• S(x,t) is the universal signature at point x and time t
• f(x,t) is the frequency at point x and time t
• P(x,t) is the positive energy at point x and time t
• G is the gravitational constant
• Mi is the mass of the ith object
• ri is the radius of the ith object
• ℏ is the reduced Planck constant
• ωi is the angular frequency of the ith object
• c is the speed of light
• λi is the wavelength of the ith object
• T is the temperature
• kB is Boltzmann's constant
• Fi is the force on the ith object
• mi is the mass of the ith object
• Qi is the heat transfer to the ith object
• ci is the speed of light at the ith object
• Vi is the volume of the ith object
• Pi is the prime number associated with the ith object
• Ni is the negative energy of the ith object
• I(x,t) is the initial information at point x and time t
• C is consciousness
• U is the universe

Operations:

• ⊗ represents tensor products (combining energy and universal signature)
• ⊕ represents direct sums (accumulating energy components)
• ∘ represents function composition (interacting frequency and positive energy)
• ∧ represents logical conjunction (connecting negative energy and universal signature)
• ∫ represents integration (over space and time)
• ∑ represents summation (over discrete objects)

I’m from United Kingdom, and have been a software developer in my current role/company for around 5 years now. I’ve always performed well in my role, receiving “exceeds expectations” in my appraisals, and not having any grievances with the business at all.
The owners of the business I worked for sold it to a much larger international business last year, and they’ve made a bunch of changes since acquiring our business, one of which was going to be issuing us new contracts on Friday (which I was anticipating a meeting for). The day before, however, I had a meeting request come through from the HR manager from the parent business and the director of our business (who worked for us before the acquisition). The HR manager explained that the company was looking to reduce its development efforts in the UK and as such certain roles were being cut loose, one of which included mine. She explained that the conversation must remain confidential between the 3 of us on the call and that instead of going through the usual redundancy process, to save time, the business is instead offering me a settlement agreement to exit the business quietly, but that my employment was terminated effective immediately and that I would be locked out after the call ended. I did not see this coming and gobsmacked was an understatement. I asked the HR manager who else was affected and how I came to be selected and she said she was not at liberty to discuss this information with me.
I did some digging around to figure out what was going on in the short time between the call ending and my account being suspended (I work remotely), and from what I discovered the only people being let go were myself (Software Developer) and the Development Manager, the other 5 developers seem to have kept their jobs.
The company offered me £5951 (around 12% of my annual salary) and an extra month’s salary, which I didn’t think was too generous considering the circumstances.
After devoting 5 years of hard work to this business, I found it to be appalling to be dropped like I’m worth absolutely nothing in a 10 minute Teams call.
I’m applying for new roles but I still can’t seem to get my head round this. I want to know why and how this came about, I’m not sure what to do - any advice?

Hi! Gusto ko lang sana matulungan 'yung kakilala ko sa nangyayari sakanya sa work nila. So first work niya 'to, fresh grad siya. Actually nirefer ko siya dito sa company na 'to kasi dito ako dati until na terminal due to redundancy ng position (pero ang totoo pinilit tanggalin ang buong department namin kasi gusto ng ets-r head siya na maging mrktg, so ayun na wipe out kami), so naiwanan ko siya magisa dun, akala ko kasi okay magiging kasama niya sa'kanya since mabait naman na bata 'yon, pero nalaman ko na lagi na palang naiyak papauwi at pina power trip ng mga kawork niya, nalaman din na kaya pala palagi siyang hotseat sa boss niya kasi nagsusumbong ng mali 'yung mga kasamahan. Pero pinapasa lahat ng work sakanya. Kaya ayun hindi na kinaya ng bata, nagpasa ng resignation, kaso mas lumala kasi nagpaparinig na raw talaga at lalo pa raw na trigger nung nagparinig din siya. Nalaman din niya na palaging siya ang usapan sa gc nung mga 'yon. Gusto ko lang sana malaman kung may laban siya, kung ilalapit ba niya sa hr 'yon dapat ba may magiging aksyon sila? Or wala?
Thank you po!

Hello everyone,
Last week, like most of our colleagues, I received the news that the company will be exiting the Dutch market due to economic issues, as it has not been able to turn a profit here. However, the company will continue providing services in other countries. I have been employed in the IT sector for the past two years under a permanent contract.
The situation is complex: we were informed verbally and then given redundancy agreements stating our roles will be eliminated. However, I believe this is not entirely true since the company plans to hire people from other countries to cut costs. To my knowledge, terminating employees with permanent contracts requires valid reasons.
According to the agreement, the company will pay severance and provide a one-month garden leave. Unfortunately, there is no work council to consult with, and the company has refused to cover legal fees, so I will be paying for a lawyer myself.
I attempted to negotiate for more time because my residence permit and the 30% ruling depend on my employment. If I don't secure a new job within three months, I will have to leave the country.
Since hearing rumors about this situation last month, I have been applying to different companies. Despite aligning my resume with job descriptions and maintaining a good format, I haven't received any interview calls, likely due to new regulations and the current market situation.
I have contacted many lawyers, but all require payment before even reviewing the agreement draft. I have decided to proceed with paying for a lawyer, but if anyone has suggestions, experiences, or knows a lawyer who might help, please let me know and share your experience.
Thank you.

I apologize if this may be redundant, but I've been searching around and reading some other posts, and it's just giving me more questions.
I'm an American citizen who will be flying from Basel to Tokyo with a layover in Paris at CDG Airport (June 8-9).
My layover will be 14 hours, so I decided to book a hotel at ibis CDG.
My ticket says I'll be flying into Terminal 2G, and departing from Terminal 2E the next day.

1. From Terminal 2G to my hotel, should I take the bus landside or airside before taking the CDGVal?
2. If I leave the airport, will I have to go through customs even if I've just flown in from another EU country?
3. When coming back for my flight, I know I'll have to go through security again. But is there anything else I'd have to do?

Thank you so much! This is my first time leaving an airport during a layover so I've just been pretty anxious about the whole process.

THE HARMONY OF ENERGY
Abstract
Introducing the "Harmony of Energy" (HoE) model, a novel formalism that posits the universe operates according to a fundamental pattern. This pattern consists of energy, defined as the smallest unit anything can be, existing as a fluid form in space, interacting with its environment through a specific method or structure, and then moving out of that space. Space, in turn, is the dynamic environment that energy occupies and moves through, filling it with positive and negative energy that affects its properties and behavior. According to the HoE model, energy moves into space, reacts to its environment, and then moves out of that space, with no time limit for how long it takes to react. This pattern is universal, applying to all aspects of the universe, and nothing escapes it.
The Origin of the Universe
The HoE model posits that the universe began as a singular entity, containing all forms of energy as one unified energy. This singularity can be represented mathematically as: U = ∫∫∫E(x,y,z)dxdydz, where U is the total energy of the universe, E is the energy density, and x, y, z are the spatial coordinates.
As the singularity expanded, the unified energy converted into distinct positive and negative energies. Positive energy is a high-frequency, high-information-potential state that retains its unique signature and individual form, capable of producing heat and maintaining its distinct properties. Negative energy is a low-frequency, low-information-potential state that loses its unique signature and individual form, characterized by a pulling force and a tendency to condense and simplify.
Initially, the universe moved in a straight line, with energy compact and cold. However, this linear movement resulted in a direct head-on collision with the void, a solid structure that hindered its passage.
This collision led to a limitation and subsequent conversion of energy, transforming it from a linear motion to a wave-like motion. The new wave motion created heat and allowed energy to break the pattern of "follow the leader" and collide with the void at an angle, shattering its edge into pieces.
This process of fragmentation can be described by the equation: F(θ) = Σ[nEⁿ * sin(nθ)], where F is the fragmentation function, θ is the angle of collision, n is an integer, and E is the energy density. For reasons yet unknown, possibly due to the singularity's energy reaching its final place or a transformation driven by cosmic "boredom," this conversion occurred, giving rise to the diverse universe we observe today.
The Void and the Ultimate Negative
Outside of the expanding universe lies the void, a region devoid of energy and matter, existing in a state of complete stillness and stationarity. This void represents the ultimate negative, a state of complete absence and zero energy density, unchanging and unyielding. As a whole, it exerts a compressive force on the expanding universe, potentially leading to contraction and eventual return to the singularity. This dynamic interplay between the universe and the void can be described by the equation: F = -G * (M * m) / r² where F represents the force, G represents the gravitational constant, M and m represent the masses, and r represents the distance between them. The void's stationary and unchanging nature, lacking any internal rotation or energy, makes it inhospitable to life as we know it.
Magnetism and Attraction: A Shift in Perspective
Initially, I viewed magnetism through the conventional lens, seeing it as a fundamental force of attraction between positive and negative entities. However, as my understanding evolved, I came to realize that magnetism operates under a different principle. Positive and negative entities are not attracted to each other; instead, they represent the intrinsic structure of things. The true nature of attraction is frequency-based, with entities drawn to higher vibrations and shorter wavelengths. This phenomenon can be described by the following equations:
F = ∫∫(μ₁⋅μ₂)/(4πr²⁾ dt dt (1)
where F is the force of attraction, μ₁ and μ₂ are the magnetic moments of the entities, r is the distance between them, and the integral is taken over time.
Additionally, the frequency-based attraction can be represented by:
f = γB (2)
where f is the frequency, γ is the gyromagnetic ratio, and B is the magnetic field strength.
Furthermore, the smaller wave's faster movement can be expressed as:
v = λf (3)
where v is the velocity, λ is the wavelength, and f is the frequency.
Energy and its Properties
Energy is the fundamental unit of everything. Energy can be thought of as an individual entity with an electrical signature vibrating at a specific frequency, carrying information from its originating source. If we were to dissect a piece of energy, we would find its genetic makeup consists of various parts, similar to binary code. One constant aspect of energy in our universe is the signature of this universe, which is present in all forms of energy, whether positive or negative. This underlying frequency distinguishes energy from our universe versus parallel universes.
Positive Energy (PE): - Oscillates through space with a frequency (f) and wavelength (λ): PE = f × λ - Exhibits wave-like behavior: PE(x,t) = A × sin(kx - ωt)
Negative Energy (NE): - Vibrates at a slower frequency (f'/2): NE = (f'/2) × λ' - Exhibits a slower, more stable behavior: NE(x,t) = B × cos(k'x - ω't)
Energy Interactions and Signature Changes
When positive and negative energies interact, their unique signatures can become altered. As energies combine, their signatures merge, releasing redundant information about the universe signature and creating an opening for new information to be stored. This process enables efficient storage and transmission of energy signatures, allowing for:

• Signature refinement and evolution
• Information exchange and updating
• Adaptation to changing environments and conditions

This process could be crucial for understanding how energy signatures evolve and adapt, and how they influence the behavior and properties of energy in various contexts.
The Formation and Evolution of the Universe
Initial Energy Interactions
In the beginning, a vast amount of fluid energy quickly interacted with the largest newly created pieces of the void, described by the wave-particle duality equation (E = hf = ℏω).
Star Formation and Signatures
As these interactions occurred, the largest of the solid structures of the universe began to form, stars, governed by the Lane-Emden equation (d^2P/dr2 + (2/r)(dP/dr) + (4πG/c^2)P = 0). Each new star held with it an old habit divulged from the singularity, a universal frequency (f = 1/T = ω/2π, where T is the period of oscillation and ω is the angular frequency). Old habits die hard, so each new star offered its own diverse and unique signature (S = Σf = ∫ψ(x)² dx, where ψ(x) is the wave function and x represents the position).
Energy Collisions and Prime Numbers
As structures formed, a group of energy travels through space with an even number of internal parts (E = 2nℏ, where n is an integer and ℏ is the reduced Planck constant). This group collides with another group of energy with an odd amount of internal parts (E = (2n + 1)ℏ), and the total sum of the newly combined group equals a prime number (P = E1 + E2 = 2nℏ + (2m + 1)ℏ, where m is an integer). New Equation: Prime Number Formation (P = E1 + E2 = 2nℏ + (2m + 1)ℏ)
Schrödinger Equation and Physical Reality
The prime number is crucial, as the extra piece gets stuck in the space it is occupying, acting as an anchor, attracting other parts to breach their negative shell and combine as one, described by the Schrödinger equation (iℏ(∂ψ/∂t) = Hψ). This converts the fluid energy to be contained into the space it is in, which is broken pieces of the void that do not have a universal size, and gives us physical reality, forming particles with diverse unique signatures (S = Σf = ∫ψ(x)² dx).
Refining Space and Transferring Signatures
As energy continued to interact with space, it further refined and shaped that space into a sphere (V = (4/3)πr^3, where r is the radius), adding the discarded portions of size to the diverse field that is the universe. During this refinement, energy was transferred to these pieces, and the signature of the star was embedded in them, forming the galaxy clusters and solar systems we know today.
Smooth Surfaces and Celestial Bodies
As any piece of something breaks, its edges are rigid, and the interaction of energy against this rigid surface knocks off the rough edges, providing a smooth surface (E = Δx/Δt = ℏ/Δx, where Δx is the change in position and Δt is the change in time). New Equation: Smooth Surface Formation (E = Δx/Δt = ℏ/Δx)
The pieces that were knocked off still contain a portion of energy that put in the work to knock it off, and this process contributed to the formation of celestial bodies and the transfer of signatures. This, in turn, led to the creation of galaxies, planets, and other celestial bodies, each with their unique characteristics and properties, shaping the diverse and complex universe we observe today.
The Cartwheel Structure and Energy Movement
The cartwheel structure represents the dynamic movement of energy in the universe, with its rotating wheel and radiating arms symbolizing the harmonious interaction of positive and negative energies. When creation occurred, energy learned how to pass through stationary space (the void) by changing its movement pattern from a straight line to a wave (λ = v/f, where λ is wavelength, v is velocity, and f is frequency). This new wave movement allowed energy to create heat (Q = mcΔT, where Q is heat, m is mass, c is specific heat capacity, and ΔT is temperature change), which was the tool that gave energy the ability to "shatter" the void and interact with the broken pieces to perform a new movement, the cartwheel. As energy moves through space, it rarefies and decreases in temperature (T = k-B, where T is temperature, k is Boltzmann's constant, and B is the energy density), causing it to slow down and change frequency (f = ΔE/h, where f is frequency, ΔE is the energy change, and h is Planck's constant).
The Block and Cartwheeling Bar Analogy
The block and cartwheeling bar analogy provides a conceptual framework for understanding the dynamic interaction of energy in the universe. Imagine a box (representing space) containing blocks of varying sizes, each symbolizing a specific energy frequency (f = 1/T, where f is frequency and T is time). The cartwheeling bar, rotating within the box, represents the harmonious movement of energy between its positive (E+) and negative (E-) forms. Each block must be 100% filled, with positive and negative energy proportions varying as the bar rotates. For example, when positive energy occupies 99% of a block and negative energy occupies 1%, the rotation of the bar causes a gradual shift, resulting in a change to 98% positive and 2% negative, and so on. This constant interaction and adjustment maintain the balance of energy in the universe.
Fundamental Forces Explained

• Strong Force: The repulsion from negative electrons being attracted to and pressing against the nucleus. This force can be described by the equation: F = k * (q1 * q2) / r²
  
• Weak Force: The outgoing frequency created by the positive nucleus, similar to energy congregating at the sun's nucleus, reacting to its environment, and breaking down before leaving (possibly as radioactive decay). This force can be described by the equation: F = (G * m1 * m2) / r²
  
• Gravity: Exists between the outer negative sphere of electrons exerting a pushing force against the positive pushing force of the nucleus, similar to the solar system's dynamics. This force can be described by the equation: F = (G * m1 * m2) / r²
  
• Electromagnetism: Energy in action, manifesting as the dynamic interplay between electric and magnetic forces. This force can be described by the equations: E = f * λ and B = (E / c)
  

Present State of the Universe
The universe currently exists in a state of dynamic equilibrium, with observable patterns and structures perpetually renewing themselves through the interactions of energy (E = hf, where E is energy and h is Planck's constant). This self-sustaining cycle is evident in the formation and evolution of celestial bodies, galaxies, and other cosmic entities, governed by the laws of thermodynamics (ΔE = Q - W, where ΔE is the change in energy, Q is the heat added, and W is the work done). The universe's present state is characterized by the harmonious coexistence of diverse energy frequencies (f = 1/T, where f is frequency and T is time), which govern the behavior and properties of matter at various scales. This balance is maintained through the continuous conversion of energy between its positive (E+) and negative (E-) forms, allowing the universe to adapt and evolve in response to internal and external influences (E+ + E- = 0, representing the conservation of energy)."
Entropy and the Conversion of Positive to Negative
The physical dimensions of positive and negative energy in a block are equal, with 1% negative energy occupying the same space as 99% positive energy. This equality stems from the different speeds of energy and their individual properties. When negative energy is at 1%, it has condensed the equivalent of 99% positive energy into a single, compact form (E = hf, where E is energy, h is Planck's constant, and f is frequency). As the proportions shift, such as 60% positive and 40% negative, the space occupied remains a 50/50 split. This is because positive energy travels at the speed of light (c = λν, where c is the speed of light, λ is wavelength, and ν is frequency), while negative energy moves at a pace relative to terminal velocity (v = √(2gl), where v is velocity, g is acceleration due to gravity, and l is length). Each form dominates at the 50% mark (T = λ/v, where T is time, λ is wavelength, and v is velocity). The percentages represent available positive energy, while the cartwheel symbolizes space or the ultimate negative in motion, influenced by energy's presence. Negative energy, with its depleted charge, occupies space that needs to be filled and recycled into a positive state. At higher percentages, collisions with negative energy slow down the flow, similar to the concept of crab mentality, where negative energy draws down the percentages.
Energy Dynamics and Galactic Harmony
The 50% Threshold
The 50% mark is a critical threshold that distinguishes between positive and negative energy. Above 50%, energy is considered positive and can produce heat beyond its negative shell. Below 50%, energy is considered negative and cannot produce heat past this shell.
Compressed Positive Energy
When the percentage of positive energy drops below 50%, it becomes compressed and can exceed the speed of light (c = λν, where c is the speed of light, λ is wavelength, and ν is frequency). This allows it to navigate through the "cracks" of negative energy:
v > c (where v is velocity and c is the speed of light)
Quantum Mirroring
Alternatively, the positive energy can align with the negative energy, resulting in a quantum mirroring effect. This enables instantaneous information transfer between entangled particles, regardless of distance:
E = hf (where E is energy, h is Planck's constant, and f is frequency)
Retaining Frequency Signatures
In this alignment, the negative energy retains its unique frequency signature to avoid interacting with other signatures:
Δx * Δp >= h/4π (where Δx is position uncertainty, Δp is momentum uncertainty, and h is Planck's constant)
The Cavendish Experiment and Energy Interaction
The Cavendish experiment, a groundbreaking study on gravity, offers an intriguing analogy for understanding energy interaction with space. Imagine the suspended spheres as representative of space itself, devoid of energy. When energy interacts with this motionless space, it's as if the spheres begin to rotate, symbolizing the introduction of energy into the internal area of space.
As energy engages with space, it's gradually consumed, much like the reduction of energy in the Cavendish experiment. This process can be described by the equation:
G = (2πLθ) / (MT)
Where G is the gravitational constant, L is the length of the torsion wire, θ is the twist angle of the wire, M is the mass of the lead spheres, and T is the time period of oscillation.
This equation, derived from the Cavendish experiment, reveals the intricate relationship between energy, space, and gravity. By exploring this analogy, we can deepen our understanding of how energy shapes the very fabric of our universe.
Energy Absorption and Frequency
Energy absorption occurs when energy slows down, allowing it to be perceived and observed. This process involves energy being absorbed by an atom and reflecting what was not absorbed. As energy slows down, it can still be observed as a wave, but just before it becomes a particle. This phenomenon is fascinating, as it reveals the transition from wave-like to particle-like behavior.
The conversion of positive to negative states is due to positives' ability to produce heat and maintain an individual form. Negative energy, on the other hand, does not produce heat and lacks an individual form, instead traveling at a pace relative to terminal velocity. This process can be described by the quantum mechanical formula: ℏω = ΔE = hf, where ℏ is the reduced Planck constant, ω is the angular frequency, ΔE is the change in energy, h is Planck's constant, and f is the frequency of the energy.
Furthermore, the frequency of the energy can be related to the velocity of the particle using the formula: f = (1/2π) * √(k/m), where k is the spring constant and m is the mass of the particle. Additionally, the energy absorption rate can be calculated using the formula: dE/dt = (2π/h) * V_uv² * δ(E_u - E_v), where V_uv is the transition matrix element, E_u and E_v are the energies of the initial and final states, and δ is the Dirac delta function.
The Conversion of Positive to Negative States and Planetary Motion
The conversion of positive to negative energy states is rooted in their distinct properties. Positive energy produces heat and maintains an individual form, whereas negative energy lacks heat and an individual form, instead traveling at a pace relative to terminal velocity. This process is reversible, as seen in fusion reactions, or can be influenced by external forces like microwave ovens.
In the context of our solar system, the sun's positive energy release generates heat and propels planets into their orbital tracks. Conversely, the incoming energy from the universe, considered negative, is cold and stabilizes planets in their tracks. Initially, I focused solely on the positive push dictating orbital paths. However, I now recognize the significant influence of negative energy and use it as the basis for understanding abnormal tracks.
Here's an added equation to illustrate the relationship between energy and orbital motion:
F = G * (m1 * m2) / r²
Where F is the force of gravity, G is the gravitational constant, m1 and m2 are the masses of the objects, and r is the distance between them.
This equation shows how the force of gravity (F) is influenced by the masses (m1 and m2) and distance (r) between objects, which is relevant to understanding planetary motion and the balance between positive and negative energy.
Gravitation and Time: Frequency's Role
Time is intimately tied to the frequency of the universe, and this relationship is governed by the laws of gravitation. Imagine the cartwheel's bar having notches, each representing a different frequency. Each notch would experience time at a unique pace, described by the formula:
t = 1/f
Where t is time and f is frequency.
If we could halt the cartwheel's motion, time would appear to pause, as described by the relativistic time dilation formula:
t' = γ(t)
Where t' is the time experienced by an observer in motion, t is the time experienced by an observer at rest, and γ is the Lorentz factor.
The passage of time is directly governed by the oscillations in the wave, or simply its frequency. By altering the frequency, we can change the flow of time itself, as described by the gravitational redshift formula:
f' = f * √(1 - 2GM/rc²⁾
Where f' is the observed frequency, f is the emitted frequency, G is the gravitational constant, M is the mass of the gravitational source, r is the radial distance from the source, and c is the speed of light.
Gravity and Energy Dynamics
Gravity can be understood in various ways through these thoughts. One perspective is that gravity operates similarly to the orbital planets, but with a twist. Instead of orbiting in space, we orbit at a subterranean frequency. This frequency attracts similar energies, leading to bonding and the formation of matter. For instance, atoms bond to form rocks, and separate rocks may bind together due to similar vibrations. However, other frequencies simply pass through, unable to bind due to differences in energy vibrations and the negative fields surrounding our bodies and the ground.
Our bodies are attracted to the Earth's core, with a force described by the equation:
F = G * (m1 * m2) / r²
Where F is the force of attraction, G is the gravitational constant, m1 and m2 are the masses of our bodies and the Earth, and r is the distance between them.
The vibrations of our energy and the negative field surrounding us can be described by the wave equation:
∇^2E = μ * ∂^2E/∂t2
Where E is the energy field, μ is the permeability of the medium, and ∂^2E/∂t2 is the second derivative of the energy with respect to time.
The incoming cosmic energy pushes us downward, with a force described by the equation:
F = (E * A) / c
Where F is the force of the incoming energy, E is the energy density of the cosmos, A is the cross-sectional area of our bodies, and c is the speed of light.
The outgoing energy from Earth moves faster than the incoming energy from the cosmos, as observed in the formation of clouds with flat bases and more sporadic tops. This can be described by the equation:
v_out = v_in * (1 + (E_out / E_in))
Where v_out is the velocity of the outgoing energy, v_in is the velocity of the incoming energy, E_out is the energy density of the outgoing energy, and E_in is the energy density of the incoming energy.
Galactic Cycles and Black Holes
The Milky Way galaxy has a supermassive black hole at its center, with a mass described by the equation:
M = (1.989 x 10³⁰⁾ * (G / c²⁾
Where M is the mass of the black hole, G is the gravitational constant, and c is the speed of light.
As the galaxy spirals towards the center, enough mass will be collected to trigger the black hole to become a large star, described by the equation:
M = (4.383 x 10³⁰⁾ * (G / c²⁾
Where M is the mass of the star, G is the gravitational constant, and c is the speed of light.
When this happens, the black hole will shed its outer shell to create the galaxy that spirals around it, and the process begins again. This cycle can be described by the equation:
t = (2 * π * G * M) / c³
Where t is the time period of the cycle, G is the gravitational constant, M is the mass of the black hole or star, and c is the speed of light.
The opposite of a black hole is a white hole, but why hasn't this phenomenon been observed? According to this article, it has been observed but misunderstood. With the theme of balancing the universe, would a large star be surrounded by much smaller black holes? Would these smaller black holes feed the larger star by way of quantum bridge or wormhole, and vice versa for smaller stars and larger black holes? This can be described by the equation:
E = (ℏ * ω) / 2
Where E is the energy transferred between the star and black holes, ℏ is the reduced Planck constant, and ω is the frequency of the quantum bridge or wormhole.
Energy Flow and Balance
Energy moves in and out of everything, maintaining a delicate balance. It enters as a positive force and exits as a negative force. Our sun emits energy at 99% strength and high frequency, which combines with an equally sized negative force at 1% strength, filling the space completely. This balance is crucial, as positive energy moves faster than negative energy due to entropy's diminishing effects over time and distance.
As positive energy travels, it loses a piece of itself, converting to negative energy. This process is directly related to gravitational forces and time dilation. When positive energy reaches 50%, it has a certain probability of converting to negative energy, which is then attracted back to a positive source with a corresponding probability of being converted back to positive energy.
This cycle of energy flow and balance is the foundation of the universe's harmony, and understanding it can reveal the intricate web of forces that shape our reality.
_Conclusion _
"In conclusion, the Harmony of Energy (HoE) model offers a novel perspective on the universe, revealing a intricate web of energy dynamics that underlie all aspects of existence. By exploring the interplay between positive and negative energy, we gain insight into the fundamental forces that shape our reality. From the smallest subatomic particles to the vast expanse of the cosmos, energy is the unifying thread that binds everything together.
Through the HoE model, we've seen how energy's harmonious movement gives rise to the patterns and structures we observe in the universe. We've also delved into the fascinating relationships between energy, space, and time, and how these interactions govern the behavior of matter at various scales.
As we continue to refine our understanding of the HoE model, we may uncover new secrets of the universe and gain a deeper appreciation for the beauty and harmony that underlies all of existence. Ultimately, this knowledge can inspire new perspectives, new technologies, and a new era of human understanding and cooperation, as we work together to harmonize our own energy with the energy of the universe.
MAG

This is something I wasn't sure about, and I just verified it at the airport, sorry in advance if this is redundant information 🙂
If you are flying out of terminal B with a Star Alliance airline (e.g. Lufthansa, SAS) and you have a United club membership, you can first go through security in Terminal C, access the United club lounge, then take the shuttle from inside the airport to terminal B without needing to reclear security. Also, the Lufthansa lounge in B is closed for renovations, and the SAS lounge in B closes 30 mins before the last SAS departure.

I was terminated by citing performance issues, and the HR could not prove a single missed deliverable by me. She just cited the opinion of co-workers that everyone feels it's difficult to communicate with you. She had not even communicated 1 single warning before this. And the reasons being cited are very vague, I understand their is redundancy in workforce, but terminating someone and not allowing the notice period pay is very wrong i believe,
I asked her to pay me my notice period salary of 90 days as mentioned in the appointment letter but she is not willing to do that.
Also HR is asking me to drop resignation email, forcing me to do so. Otger wise she'll mark it as terminated.
Please me guys what should I do, she has already disabled my credentials. Asking me to send resignation via personal mail.
Please help me out guys. What legal options i can look for? I need atleast 2 months of notice pay. She's just giving me 30 days pay.

legaladvice #labourlaw #help #layoff #justice

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MNS Oengro

“How’s the fuel status of the Oengro?” Grionc asked.
Vastae, eyes glued to his console, replied without hesitation. “We have just enough blink fuel for one jump, but we aren’t going anywhere once we get to the other side without a refueling ship.”
“One blink is all we need. And if the Oengro is good to go, the other, smaller ships should be fine too then,” Grionc responded, bringing up the system map on screen with her paws. “Four minutes to blink limit. Have the ship’s crew secure themselves for the blink and get ready for shift change to execute post-blink procedures when we arrive.”
“Yes, High Fleet Commander,” Vastae acknowledged with a brisk nod.
Suddenly, three quarters of the sensor readings on her sensor board disappeared, and the fidelity on the remaining took a nose-dive in accuracy. A low murmur ran through the sensor stations, which she waved away with a paw. “No need to panic. It looks like our friends jumped before we did, as arranged. Our sensors are on their own for now.”
Vastae swallowed hard. “Are you certain about this plan, High Fleet Commander?” Vastae asked nervously. “Not that I don’t trust what Sphinx— Speinfoent cooked up, but this is a last-minute plan modification we haven’t rehearsed. And with our fuel situation, we only get one chance here.”
Grionc put a calm smile on her face. “Remember that exercise we did with the Grass Eaters a while back?”
“Which one?”

4 months ago

“Since it’s New Years, it’s time to have some fun,” Mark announced with a grin to Grionc and the rest of the curious bridge crew. “I’m going to show you guys a fun teambuilding exercise we did on Terra.”
“Teambuilding exercise?” Grionc asked suspiciously.
Mark didn’t let her skepticism color his enthusiasm. “Well, I’m not sure how much teambuilding it does, but it is fun. And I have never seen aliens do it. In fact, this might be the first time this has ever been done outside of Sol!”
“Fine, fine. What are we doing?” she relented.
“This exercise is what we call the trust fall.”
“The trust fall?” Grionc repeated. “It’s about building trust? Like trust in your crew?”
Mark nodded vigorously. “It’s supposed to. I’m not sure if it truly works, but it truly is fun. You and I can demonstrate for the crew.”
Grionc sighed. “Sure. What do I do?”
“Come stand over here,” Mark pointed to a spot on the floor, and then stood in front of her with his back to her. “What I’m going to do is I’m going cross my arms… like this… and on the count of three, I’m going to fall backwards, and you have to catch me when I do.”
“Huh. That seems dangerous. What happens to you if I don’t catch you?” Grionc asked, mild concern creeping into her voice.
“Traumatic brain injury, probably. Something similar for your species too, I assume,” Mark shrugged nonchalantly. “But don’t worry about that. We have good medical facilities on the Nile, and you will catch me. That is the point of the exercise. Alright, you ready?”
Sensing his insistence, Grionc sighed and held her paws out, bracing herself. “Ready.”
“One, two, three…” Mark did as he described, crossing his arms, and falling backwards into Grionc’s outstretched arms. She grunted with slight effort as she intercepted his fall and then gently lowered him onto the ground, “Oomph. Huh. You Terrans are lighter than you look.”
“Yeah, my bones are nano-grafted,” Mark grinned, bounced up to full height, and circled around her back. “Okay, now it’s your turn.”
Grionc crossed her arms and held her breath for a moment. “One, two…”
She didn’t move. A few seconds later, she let go of her held breath. “I can’t.”
“What? Why not?”
Grionc muttered excuses. “No, it’s just— my tail— our balance mechanisms are different, I can’t just fall backwards on purpose—”
Mark insisted. “It’s not that difficult. Just let go. Don’t worry. I’m right here. I promise I’ll catch you.”
She held her breath once again, psyching herself up for a few more moments.
“One, two… doh, I can’t.”
Mark lightly patted her on the shoulder. “That’s okay… don’t worry… Hey, Speinfoent, come over here and give her a light shove. Alright, on the count of three. One, two—”
“Oh, no. Don’t you dare! No! Don’t touch— Yowwwwwww!”
Grionc continued, “And now… we fall. And we trust that our new friends will be there to catch us.”

ZNS 2228

“They’ve blinked,” the computer officer reported.
“Did we catch their blink vector?” Skvanu asked urgently.
“Calculating… got it! We triangulated their blink vector and probable destination! Entering it into our fleet navigation computers,” she responded, paws flying over the controls.
“How long before we can execute the blink?” Skvanu pressed.
“Two minutes before we hit the limit ourselves,” she replied, not looking up.
“Good, get the crews ready and start the countdown. I want to blink the millisecond we are clear of the system limit. And get all systems ready for what’s on the other side. They almost definitely have an ambush waiting for us. I’m guessing that’s where the remaining nine or so squadrons of Sixth Fleet are waiting for us,” Skvanu said confidently. “Twelve Lesser Predator squadrons to twenty-six of ours. Doesn’t matter how many upgrades they have, we will defeat them, especially since the first three will be within railgun range. Get those gunnery crews and point defense computers ready.”
“Blinking in seventy seconds,” she announced. “Sixty-five seconds—” Suddenly, she stood up, “Eight Whiskers, our FTL communications are open again! Both Datsot and Gruccud have just responded to our last message!”
Skvanu spun around to face her. “That makes sense. Whatever device they used to stop our communications must have been on one of the ships that just blinked out. Is there any priority intelligence from either?”
“Yes! Datsot has an emergency transmission for us. It’s from Ten Whiskers Ditvish!”
“What is it?” Skvanu asked, his voice serious.
She began to read. “Lesser Predators have entered Datsot system in force. Nine squadrons spotted so far. They may attempt to engage our garrison force there… His guidance is that we return immediately to trap these aggressor ships, but leaves the decision up to you…”
Skvanu absorbed the information with shock. If those ships are really in Datsot, they must not be on the other side of wherever the Oengro is blinking. And with that context, this now smelled exactly like a planned trap.
He thought out loud. “This must be what the Lesser Predators planned from the start. If we chase, we have no idea what they have on the other side. There may be refueling ships. They may have already gotten away. By the Prophecy, they may even be sacrificing three squadrons to get us to blink through a singularity or anomaly. But wait… If we return to Datsot immediately, we might catch those squadrons split from the rest of their ships and cripple their fleet!”
Having made up his mind, he shouted urgently at the navigation station, “Navigation, hold the blink!”
“Halting the blink procedures.”
“A handful of ships have already completed the blink!” the computer officer reported, almost in a panic.
“Cease blink procedures! Fleet-wide, cease the blink!”
The order went out immediately, and it was a testament to the discipline of the Znosian Navy that most squadrons managed to stop the countdown just seconds before it went through.
“How many ships went through?” Skvanu asked urgently.
“We managed to stop most of our ships, Eight Whiskers. Only five combat ships from Squadron 6 went through.”
He sighed in relief. “Only the Prophecy can help them now… Turn us around. Let’s get back to Datsot.”

TRNS Nile

“I think we are in sufficiently deep space,” Captain Gregor Guerrero said to his crew. “Drop us out.”
“Yes, captain. Emergency drop-out in five… four… three… two… one… now.”
The ship shuddered and creaked as the emergency-stop was activated. The blink engine wound down, forcing the ship back into normal space.
Gregor turned to his navigation officer. “How far from Plaunsollib did we travel, in regular space?”
“Two months on their Alcubierre drives if they combat burn with all their fuel. Four if they plan on stopping,” she replied immediately. “They’d be going too fast to aerobrake anyway.”
“Good,” Guerrero said, gluing his eyes to his sensor board. Ships in FTL are difficult to detect, even on gravidar, but the state-of-the-art technology on the Nile gave them a few seconds of warning.
A few seconds later, the sensor officer’s voice cut through the tense silence. “I’ve spotted the Puppers in blink! All of them, tight formation. They’ll pass us in about fifteen seconds.”
Guerrero nodded his pleasure. “Good, let them pass. Tell me when they’re out of range.”
The seconds ticked by. “Ten… five… they’ve passed our position… and now they’re out of range.”
“Now, switch on the blink disruption field,” he ordered.
The hum of the ship’s ambient noise went up an octave, signaling maximum power drain as the ship’s thirstiest system kicked in.
Gregor looked at his information panel. “Full emissions control. EMCOM Alpha. Deploy the FTL jammer drone and then shut off our engines. If things go well, we’re about to be joined by half the fucking Bunny Navy in a minute.”
“Aye, Captain. EMCOM Alpha.” The rest of the crew nodded, working their controls with practiced competence.
“Jammer drone out. You think they’ve got wild weasels, captain?”
“Unlikely, but we take no chances. If they don’t…” He shrugged. “… we’ll just get our drone back later.”
A tense minute passed, then the sensor officer reported, “Captain, Znosian ships spotted on gravidar! Two… three… five in total… They’ve just been forced out of blink.”
“Five squadrons?”
“No, Captain, five ships.”
Gregor furrowed his brow, surprised, and took another glance at his console. “Only five ships?”
“Yes, sir.”
“Alright, keep the disruption field up, and analyze the drive signatures on them. Maybe one of them is this Skvanu guy we’re supposed to hit,” he speculated hopefully.
After half an hour, Guerrero finally called it quits. “No more guests are showing up. Looks like they must have wizened up at the last moment.”
“Aye, sir,” the executive officer said, shaking her head in disappointment as well. “It was a good plan. Could have stranded their whole fleet out here.”
“Well, bad luck— these things happen in war, Lieutenant. Don’t worry. We’ll get them next time. How are the guests we did get doing?”
“Out of blink fuel, as expected. They’ve been dumping cargo in an organized fashion. I think they’re planning to see if they can reach Plaunsollib with their subspace drives in a reasonable amount of time and call triple A.” Then, she asked, “Where do you think the rest run off to?”
“Probably Datsot,” Guerrero guessed. “Phone Sphinx and tell him he’s probably got the whole shit storm heading his way, ETA about a couple days. Get the estimates to him.”
“Yes, sir.”
“Now, we just need to silence the witnesses so we can use this trick again. Bridge to CIC: let’s keep it simple. One Kestrel for each of the targets. We’ll swiss-cheese them with railguns after. Just in case.”
“Aye, Captain. We’re not dropping off those TRO drones here, are we?”
“Nah. Too much work. No one is finding these guys ever again anyway.”

MNS Trassau

“I just got off a call with the Nile,” Loenda announced. “Looks like the Grass Eaters have discovered our ruse in the other system. The main enemy fleet is heading our way right this second.”
Speinfoent sighed, and suggested, “If we burn closer for just half a day more—”
“No more,” Loenda declared. “We are already risking nine squadrons coming this far into the Datsot system limit.”
“Alright,” Speinfoent agreed reluctantly. “We can still give them a present they won’t forget any time soon.”
“That, we will. That we will.” Loenda turned to her console. “All ships in Battlegroup 2, dump your payloads as quietly as you can. Then wait half an hour to change your vector and make your way to the system blink limit.”
“Yes, Battlegroup Commander.”

ZNS 1841

“Ten Whiskers, the Lesser Predators are turning around,” the computer officer declared, doing her best to hide her relief.
“What? Where are they heading now?” Ditvish asked, confounded.
“Towards the shortest path to the system blink limit, I think.”
“That’s it? They’re just leaving now?”
“Combat computer speculates that they might have seen that Eight Whiskers Skvanu is heading back to Datsot, so they are breaking off the attack,” the officer offered.
“That’s… not very Lesser Predator of them, but very logical,” he admitted. “They must have realized their plan failed and are now cutting their losses.”
He didn’t mention that his fleet was the one that came out behind, losing yet another precious supply convoy and then sending the whole combat fleet on a wild predator chase for nothing. That State Security goon might start to become a problem if he didn’t spin this well in his after-action report.
A few hours later, a foreboding feeling coloring his mood, he ordered, “Sensors, boost our radars towards where they changed vectors. I want to check to see if they dropped any drones or traps.”
“Yes, Ten Whiskers.”
The 1841 boosted its radar towards the direction, blaring out signals on maximum strength and—
“Incoming… missiles? Ten Whiskers, many missiles! Dozens! Over a hundred! They’re well within our minimum abort range!”
“By the Prophecy!” Ditvish exclaimed. “All ships, execute combat burn away from them! Countermeasures and fire counter-missiles, at the ready! Track those missiles!”
Fortunately, the garrison fleet was still in high readiness from before. Their engines were ready to light up to full acceleration immediately.
Unfortunately, the missiles were already close. In desperation, his ships began dumping their entire loads of radar chaffs and flares into space behind them as they maneuvered away from the threat. Counter-missiles sped out of their tubes towards their rear, relying on their motherships’ sensors and radars to find the tiny alien missiles for them to engage.
Quietly gliding through space towards the enemy on inertia inherited from their motherships was the sizable swarm of Terran-made missiles. Obsolete for military purpose in Sol but still produced for the civilian and gray market, they were an easy addition on the TRO’s shopping list. Vast quantities of them had found their way into various shell corporations and dead drops all over Sol, then onto hastily constructed exterior pylons on Sixth Fleet ships.
While they were indeed several times outside of the maximum effective range of the Znosian ships at launch, missiles technically did have unlimited ballistic ranges in space — if their enemies were not moving and they did not need to constantly fire their thrusters to adjust course. Relying on a short first burn and then inertia, they flew most of the way towards the stationary enemy fleet completely undetected. By the time they were spotted, it was too late; the Znosians were well within their effective ranges.
Their intelligence chips might not have been super-Terran state-of-the-art computers, but the Pigeons had no problem realizing that they were discovered. They had been tracking the enemy targets using passive infrared sensors that did not alert enemy threat sensors to their presence. But the second that the targets started dropping flares to blind them, they activated their primitive late twenty-first century radars and homed in onto the priority targets they’d been given. Their main thrusters began their burns, adjusting their vectors to intercept the now-finally-moving enemy ships.
Then, they saw the incoming counter-missiles — fired by the enemies sporadically, obviously in panic.
The makers of the Pigeons might not have bothered to include next-generation electronic dazzlers on them, but penetration aid on missiles had been standard in Terran warfare for a century. They littered the space they were in with chaff and their own bright flares, coordinating with the other missiles in the area with short range laser communication to ensure that none in the swarm would confuse or disrupt each other.
The Znosian counter-missiles were certainly confused and disrupted though. Many veered off into phantom signals. Some lucky ones did manage to find their targets. When a few of their comrades dropped off their impromptu mesh net, the Pigeons constantly corresponded with laser communications to re-prioritize their targeting.
At the top of the list was the fattest, easiest target of them all: the enemy flagship 1841.
Seconds before impact, the missiles finalized their targets, and they spent every drop and fume of their remaining fuel on terminal maneuvers.
The Znosians’ close in weapons systems had milliseconds to engage the incoming threats. They performed admirably… for trying to deal with this unknown alien threat for the first time. A couple dozen more missiles were plucked out of space, but it was not enough.
Not nearly.
The rest slipped through the net.
Miraculously, the 1841 managed to survive initially. Despite it being the primary focus of the Pigeon mob, the other ships did their best to shield its most vital components in its rear with their own point defense. And the Pigeons — like most missiles of its era — were loaded with just enough firepower to destroy much smaller Terran ships. The larger hulls of the Znosian ships gave their obsolete mid-century intelligence chips a slightly more interesting exercise in module identification and targeting.
The massive Thorn-class battleship took fourteen hits to varying systems that the missiles visually identified as “that looks pretty important” on their final approach: its primary missile and gun tubes were trashed, venting atmosphere to space in those compartments. A proximity hit near the stern took out four of its eight massive main thrusters and several system modules at the rear of the ship. And perhaps worst of all, one Pigeon managed to zero in on its vulnerable front bridge, the explosion emptying its contents and occupants into vacuum.
Luckily for Ten Whiskers Ditvish, none of them hit the armored flag bridge where he was in the belly of the ship, vindicating the Znosian Navy’s practice of separating the two for redundancy.
Nonetheless, Ditvish fell to the ground as the simultaneous impacts temporarily overloaded the inertial compensators and shook the ship to its core. Sparks flew around him, and he smelled a pungent stink as the automated fire suppression systems kicked in to save as much as they possibly could.
He slowly climbed to his feet and looked at the scene around him. A sensor officer was spraying foam at a small fire with a handheld device, successfully extinguishing it in seconds. Several other of his crew were recovering and returning to their stations with remarkable calm. After all, they were elite, well-trained spacers and officers of the Znosian Navy.
Ditvish did the same, propping himself back into his command chair with slight effort. He operated his console in a concussed daze. One glance at the status board told him that the 1841 was a write-off. It wasn’t going to be combat effective ever again. At least its life pod systems were working, and he watched in relief as dozens then hundreds of crew members in the damaged sections of the ship climbed into theirs and ejected into the relative safety of vacuum.
He checked up on the other ships: several others were hit. Six had outright detonated: no survivors nor signals came from them. Two were irreparably damaged, their remaining crews also abandoning their ships in an orderly fashion. And another six had visible fires or scorch marks on their damaged hulls, but those crews were still valiantly fighting to keep their ships alive.
Ditvish noticed that the missile didn’t go for all his ships, just the ones on the outer edge on his sensor board— wait, the missiles—
To his horror, several more dozen missiles they’d detected were still active, and they were going for—
He looked at his computer officer’s station and yelled, “We have to warn them!”
She yelled something back at him, but he realized that he couldn’t hear her. Hitting the floor must have injured his hearing organs. He yelled again, hoping that she could still hear. “Warn the orbital support fleet! The logistics and fire support ships! Evasive maneuvers and take cover in the atmosphere!”
Her lips moved again. He got out of his chair and stumbled over to her in a daze, trying to hear what she was saying.
She was saying something.
It must be important.
“… not reach them. Our communication array… destroyed! Ten Whiskers, we need to get… We don’t have much time!”
Ditvish finally understood her from reading her lips. He didn’t respond. Just numbly watched the planetary battlemap of Datsot on the main screen.
It didn’t take long. They were completely defenseless.
The remaining missiles plucked every last orbital fire support and logistics transport ship out of the skies of Datsot. Most detonated; a few left behind trails of black smoke as they sank uncontrollably towards the planet’s surface.
Then, Ditvish’s hind legs gave out and he crumpled onto the bridge floor.
He was dimly aware of one of his subordinates dragging him towards the bridge escape pod as he blacked out.

MNS Trassau

“Don’t worry, Speinfoent,” Loenda said, putting her paws around the junior commander looking glumly at the image of Datsot retreating from their view as the rest of the bridge cheered the better-than-anticipated success of the raid. “We’ll come back, and next time, we’re coming back for everything.”
“That we will, Loenda. That we will.”

Meta

There is no research that shows the effectiveness of trust falls for building trust in a team and plenty of research showing that falling backwards from a full standing position without adequate bracing or padding can lead to serious brain, spinal, and back injuries.
Coercion or retaliation against Malgeir employees who refuse to participate in trust fall exercises may be considered investigable or actionable violations of workplace safety regulations by the Republic Office of Occupational Safety or anti-discrimination regulations by the Office of Equal Opportunity.
Whistleblowers are entitled to up to 25% of monetary penalties recovered. If you see something, say something.
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Chapter 53: Apostasy

Ethernet has landline 1900s phones two pairs wires reserved in the spec sheet its 8 or so wires when crimping the ends uses like two with one for ground and one seemingly empty and then has two for phone and some unused, with old 10/100 baseT coax with terminating ends exactly like optical or coax 90s cable TV with optical fiber 99% of the way just your block has coax to the rest which uses the 'same'DOCSIS data over cable standards as fibre optic.. just slightly worse latency and bandwidth is calculated by latency things like wifi lan has like 11 channels or 15 channels of frequency which optical calls wavelengths of light. A 2015 or around there linus tech tips video of him going to a swedish lan party called dreamhack had a bunch of multiple redundant 8Terabit or was it bytes of fibre optic internet they explained with light having 7 colors but having 8terabytes of bandwidth with different wavelengths of light called frequencys or a better term for optics is known as LASER ARRAYS of light at fixed frequencys that often plugs into the PC via ethernet cables or whatever for a gamer lan party or home/residential or small businesses at realistically within budget of anything with enough users to require that bandwidth or 'web hosting or web servers' you dont need to be an undersea cable or international link with 200terabits plus for an internet exchange to your main CBD or the fastest like the netherlands IX...
So the problem im trying to solve is, here in australia we got our undersea cables done wrong they kept breaking and we didnt have a navy or defense force securing our countrys communications to prevent war crimes and keep us connected to the global banking systems or whatever.. and then when our biggest telcos cable or fibre all had dialup speeds for around 2 weeks in the early years 2000s to force us to pay other countrys to connect to their links and be ' end of the line' maybe paywalled or proxied off the internet randsomewared to connect to and borrow bandwidth from other countries satellites and other countries undersea link cables which truly were indestructible to any cruise liner ships anchors whatever being flexible giant steel braided cables big as a CAR when australia finally paid to lay small sections of that stuff to link up to others and not pay randsome to internet butt bandits or have private businesses and multi nationals run their own links and ignore the public our lack of a defense force actually let somalian pirates literally somehow pick up and walk off with our expensive undersea car sized cables filled with a few arms thick of hair thin fibre optics which is cheapest clear resin enamels plastics about $3 not sure if USD per kilometer and resembles modern glass/glazing. How does anybody steal that stuff without people noticing like you cant just load it onto a truck and drive away? or a boat? if only satellites and some sort of defense organization existed to prevent us from being impersonated or whatever.. So now in australia ANYTHING with words like gigabit costs a fortune for a mainboard or switch or ethernet hub.. but the ancient 1900s 10/100 telephone land line wires of ethernet 10/100 clock in at a whopping 13 or so mhz sometimes 27.. and 60 or more mhz for like gigabits and whatever it increases shockingly fast with each mhz clock cycle as its units of work over time in nano seconds or zeptoseconds you see billionths of a second nano second RAM and PC with windows realtime kernel actually uses like ryzen hardware negative latency faster than reality freely syncing with any device in the universe and fixed mhz frequency bus can drive like 50 to 100 or thousands of GPU's and HDDs and monitors or whatever from the one modern multicore PC or whatever.. 90s AMD business server still holds world records for most connected devices though it had stackable CPUs opteron and would have used infinity cache type stuff probably software 3dnow and evolving game worlds tech of 80s and 90s AMD gaming evolved advertising.
So in australia anything gigabits costs hundreds of dollars for a switch router some thousands for lots of ports.. but its the shittiest weakest bandwidth ever with mhz and performance miles short of a raspberry pie or whatever. I had to pay a fortune for a mainboard with 10gigabit LAN port and everytime i got a high speed LAN port its been broken or missing so some pricks can sell ebay routers or switches for thousands here.. not knowing why its so expensive is youre paying fortunes for any real bandwidth because australia has to pay literal somalian pirates for their internet connections or privately owned businesses like telstra for access to their private links and glares at countries like new zealand and hawaii for being super technologically superior.. a cheap USB ethernet adaptor costs under 10 bucks on ebay or whatever and is maybe gigabit and your switches and routers 90% of the time you want the cheapest UNMANAGED switch possible. Yet the mainboard i recently purchased ASUS pro art creator x670E i recall had an issue with some asshats trying to steal pathetic measly 40gigabit USB4 chips from all the boards at the computer store to sell on EBay as other junk, when anything in the universe with an M.2 ULTRA slot does 40gigabits since PCI express 3.0/4.0 as PCI express 3.0 SSD drives famously use a specific I/O controller chip which gives them 38gigabits 550MEGABYTES PER SECOND for just about every SSD in the universe minimum constant fixed performance clock frequency of operation no moving parts all day everyday always 550megabytes per second. 550MB of the ultra M.2 slots 40gigabits of bandwidth in that one slot each PCI express lane or channel has a total of.. well google it yourself for an AMD pciexpress board x270 x470 or x570 board or a threadripper gen 1 or ryzen gen 1 board and its 120 pci express lanes controller or whatever. But for a couple years when AMD had pci express 4.0 and better than M.2 ultra intel was playing catch up on PCI express 3.0 and still had regular m.2 in all their boards until AMD was ready for pci express 5.0 my friend on intel bought the same NVME drives and complained they had corruption errors or issues i later learned his board wasnt fast enough and he was maybe trying to use the samsung magician RAM disk and enable NVME features and functions intel maybe did not yet support.
So.. why is USB 4 so many years late and why is it so dang expensive when terabits of ethernet or anything optical is like the cheapest stuff ever and comes with every internet connection since the 90s at the lowest cheapest mhz and 1900s land line wire telephones ever, remember digital isnt a physical thing and everythings literally analog with a sensor or multimeter whatever mathematically translating it to a graph or algebra equation mapping it into different values digitally +10 -10 whatever using microphones or camera sensor whatever. the gigabits tax and uhh LAN port taxes for dumb gay australians being literally see it via satellite outerspace levels dumb and gay astrogaylian should not apply to the cheapest of raspberry pie free 3d print or laser CNC yourself something computery like risc V for the cheapest of USB flash drives or memory cards etc.
I get intel pretends to have invented court ordered USB to probe their hardware after it was proven to have used other peoples code and chips by the chip makers and them selling computers with keyboard and mouse hardwired in so you bought a whole new computer when a key broke on the keyboard couldnt replace them.. and every other device had USB but theirs didnt free open standard and it kinda being the only way to connect any device in the universe and freely sync with it (mics/phones whatever).
why is 1900s phone tech ethernet so dang expensive to go from 20mhz ranges to 80 or whatever mhz ranges or use something very similar to 90s optical audio SPDIF output or anything remotely like a laser in australia? and who would be dumb and gay enough to be so financially retarded as to think that USB 4 was expensive or special as to steal it? am i... missing something?
also before you complain, but ethernets not the same as USB you cant power over ethernet or use your houses electrical wires as ethernet. You also cant use ethernet for monitors or displays, and its not like you can extend HDMI range limit of a about 10 to 15 meters by swapping its ethernet wires with optical ones for it to maintain its HDMI 0 latency spec or type C USB 0 latency spec. USB lets you connect heaps of devices you cant do that with an internet or ethernet for things like keyboard and mice or monitors or whatever. I understand what you mean power over ethernet or PPOE standards suck theres no way those are a thing. using devices over the internet and not the intranet who does that? thats so dumb. remote administration, theres no such thing youre mistaking malware or rootkits im sure. you cant connect a heap of devices up or entire computers to a ethernet port thats the dumbest gayest thing i've ever heard in my entire life! My gaydar is going off and it looks like the wifi symbol.
when trying to use anything ethernet with lame awful bandwidth thats limited, on my AMD board where the website images show AMD ethernet lists as marvel yukon controller i cannot use as its maybe broken there no light on the back, in devices managers advanced tab you can see the send receive or transmit buffer sizes and countless other ethernet settings are MISSING or a blank space. and are limited to 128 on send and 256 on receive up to 4096 or whatever max. But low latency 128 or 256 is maybe best but not all are an option and most networking features on the intel LAN adapters are missing countless advanced ethernet properties and settings because they're fake and lousy and the worst latency ever and they literally seem to swap your windows kernel out with something not realtime so you cannot ever hope to record or playback audio or video or anything close to a video game in hopes of slowly selling it back to you. Linux distros did this too its the dumbest thing ever that to hear or record or playback or play games you must patch in a realtime kernel for free to game like its the 80s and 90s or DOS or whatever. most 90s PCs were CAS 1 or lower nanoseconds. DDR 3 1600mhz depending the maker might be CAS1-4 latency. How can we verify our kernels are correct? and our ethernet and I/O bandwidth is correct? the youtube video about linus tech tips dream hack lan party of gamers in sweden was edited and reuploaded by illiterate asshat buttpirates maybe from somalia or the ones randsoming us some of their internet connections as a proxy piggy back on the international links as we dont have a defense force or army or whatever and dont know what war crimes are or why they are or what the heck a bank is and sure as shit dont know the cost of anything cheap USB or LAN. The dreamhack linus video falsely shows as 6TERABIT. they wanna steal 2TERABITS of EVERY optical or ethernet devices which isnt the government doing it if they wanna see whats in your computer they can document their reasons of why which is what a warrant is they dont need one if they believe a crime is occuring and literally take the computer by law to inspect it then give it back when nothings wrong they leave you a claim ticket and have you document it at the nearest policing station or whatever fill out forms sign 'they are taking my PC and i can get it back when it wasnt used for crimes." when australia doesnt technically have an internet and doesnt technically have RAID arrays which is required to use USB or SSD or NVME or storage tech with no moving parts and multicore a 2TB SSD is twice as fast and often has 2x 1TB wafer chips in there figure it out the IO controller chip supports many and you can buy the cheapest USB sticks with like 16terabytes of storage space i just see a $extend folder or uhh file format header thingy in the partition in my mainboard bios on that particular drive and using any cheap SSD or USB devices makes linux cry about the partition managers cant write or read extending past the storage limit. it doesnt take a genius to figure out what dumb gay fags the whole internet is.
infinitybitdepthinfinitygraphicsinfinitypixelsinfinityresolution.7z ~ pixeldrain

As a veteran of HD1 and the first galactic war I am absolutely appalled at the state of the game’s current arsenal. There are some fun and unique weapons here and there but most of them just feel redundant or terrible. Nowhere is this more visible that the AR, SMG, and DMR lineup. Here is a rework I’m proposing to high command ti ensure we are given proper tools to ensure the safety and spread of managed democracy.
Gun Rebalance and additions ARs Class Role: Rifles are designed to put holes through targets, and they need to reflect this role better. All rifles with Light penetration have been upgraded to be Light armor defeating. This means that while weapons with Light AP will damage light armor, they won’t always fully damage it. While rifles with light armor defeating fully negate light armor and deal full damage to it.
Liberator, 65DMG, Excellent ergonomics, the best weapon for firing on the move, +1 mag Role: Extremely easy to control and ideal for new players or veterans looking for something reliable. Capable of 45/45/4.5/ delivering 45 rounds at 45 meters in 4.5 seconds on target with no effort. Lore: High command has started production on upgrade kits for our standard rifles to improve it’s handling. Liberators now come with a vertical foregrip and a new muzzle brake to better control the weapon.
AP Liberator, 70 DMG, +5 rounds, Slower reload, 23 recoil, bad ergonomics, Uses AR scope Role: This Frankenstein of a gun is not for new players, uncomfortable recoil, and unfriendly handling in exchange for uncompromising stopping power. Terrible when firing on the move, with significant muzzle climb. But it provides rapid armor-piercing fire to those who can control it. Lore: The Penetrator started its life as a converted liberator modified to better penetrate armor. However there was no standard for how this would be achieved, so the conversion differs from regiment to regiment. Typically it involved sawing off a diligence barrel and converting it into a squeeze bore to increase velocity at the cost of terminal ballistics without using new ammunition. High Command has now realized the potential usefulness of a standardized conversion for its service rifle. Fabricator schematics have been published for new components and manuals for a consistent conversion. As part of project Ironbreaker, an initiative to outfit soldiers with better AP weapons, Production has begun on a variety of new ammo for the weapon which is much more powerful. The new 5.77mm Talon round generates 3x more chamber pressure than the liberator. The weapon itself has a new chamber and a properly machined barrel, made from surplus diligence rifles. The new AP liberator is also outfitted with a standard rifle optic, Punisher pump grip for a vertical grip, 35 round magazine, and a grey and red color scheme to denote its new changes.
Adjudicator, 90-100 DMG, 720 RPM, 30 recoil, Burst fire, uses the DMR scope Role: Battle rifle, Ideal for long-range combat, Semi-auto for small targets or precise shooting, Burst fire for large targets or close combat. Sluggish ergonomics but surprisingly controllable. Lore: Designed to replace liberator rifles on specific fronts where armored enemies are more common, the adjudicator was met with mixed success. The weapon proved to be reliable, powerful, and accurate but failed to fully replace the liberator in an assault rifle capacity. However, the 17th Helldivers regiment came up with a brilliantly effective modification. The outfitted the weapon with a reciprocating barrel shroud and a burst fire mode to turn the rifle into a long-range killing machine. With a surplus of Adjucator parts piling up from the weapon’s failure, High command has made this modification the new factory standard for all Adjucator rifles. The added weight and complexity in exchange for what has been reported as a 50% increase in accuracy seemed to be a fair trade.
Tenderizer, 840RPM, 75-round drum, 12 recoil, 4 mags, Terrible reload, Okay moving accuracy Role: IAR, ideal for laying down sustained fire on targets, can mow down multiple targets quickly. Low magazine count and high RoF make this weapon prone to running out of ammo. Lore: A new development to supplant the more expensive and time-consuming liberator rifles for SEAF army troopers, the Tenderizer was an unwelcome addition. It was heavier, bulkier, and awkward to handle. However, the increased bulk made it easy to control during sustained fire and it was very reliable under this strain. Troops began jury rigging drum magazines to use it as light machine guns. With a sizeable surplus of the liberator’s 5.77mm ammo, High Command began testing a designated IAR (Infantry Automatic Rifle) variant for helldivers use. This variant was an instant success providing individual hell divers with team-level firepower in a rifle-sized package.
Blackout(New), 85DMG, 420RPM, 24 round mag, 8 mags, superb moving accuracy, Silenced Role: Ideal for stealthy missions, the blackout deals very high damage at close range, while enabling the user to remain undetected from nearby patrols. Not effective vs armor Lore: Developed for Blackguard operatives, the Blackout is an integrally suppressed rifle created in response to the rising automaton threat. Veterans of Maevelon Creek petitioned High command to develop a new rifle, able to quietly eliminate bots while still being effective against devestators.
Yari(New), 45DMG, 1400RPM burst, 900RPM salvo, 36 Round magazine, 10 mags, AP Role: Prototype rifle with lightweight Sabot ammunition, fires a 3-round hyperburst and a 6-round salvo. Exceptional ammo efficiency and power at range lacks close combat ability.
DMRs(Classwide rework) Role: DMRs are designed to put rounds where rounds need to go while also being able to be used alongside assault rifles in a firefight. In Helldivers DMRs take an unconventional role of being viable against light target while alos enabling the user to defeat larger enemies like devestators and bile spewers at long range. To start, DMRs have a new bonus, DMRs deal +75% extra weak point damage (Headshots) and deal 10% more damage per point of AP they have over the target region. So they do extra damage if they hit the soft unarmored bits as well as on headshots. They also receive 50% less recoil while prone to better provide accuracy at range. DMRs are for the methodical sharpshooter who prefers to pick off targets at a distance instead of charging in, rewarding careful positioning and shot placement with heaps of dead foes.
Diligence, 120-140 DMG, 22 Round mag, 30 recoil, 8 mags, Full auto mode, Silenced Role: Starter DMR that delivers high damage at long range while keeping the user concealed. Silencer isn’t as effective at close range, but great for staying hidden during firefights. Lore: High command has witnessed the substantial failures of their DMRs and has issued a complete recall of the weapon. A brand new receiver and chamber system has increased its muzzle velocity by 500 feet per second, greatly increasing lethality.
Diligence CS, 175-200DMG, 18-round mag, 6 mags, Staggers on full damage hit, Thermal optic Role: This more demanding variant of Diligence rewards more precise shooting with higher damage. It is better at stopping large targets but is less effective at picking off enemies. Lore: as part of the Ironbreaker initiative, many weapons are being issued new nitro ammunition. The diligence CS has undergone a more extensive upgrade. A new barrel and chamber designed to maximize lethality with the new ammo has greatly increased stopping power. The CS can stop devastators, bile spewers, berserkers, and similar targets with just a few hits. It has also been outfitted with a thermal sight to see through fog, sand, gas, and smoke.
Retribution(New), 275 DMG, 8 Round mag, Bolt action, Rounds reload, Silenced, AP Role: Longest range DMR, remarkably quiet and powerful, ideal for dropping large targets and protecting teammates from range.
Wyvern(New), 110DMG, 360 RPM, 26 Round magazine, 8 Mags, AP, Full Auto capable Role: Assault DMR, designed to be used aggressively at close range while permitting the user to provide long-range support.
SMGs (Classwide rework) Role: SMGs put holes in targets, not through them. SMGs have been largely replaced by Rifles in modern warfare, the same should apply to Helldivers. This shouldn’t make the useless, but instead good at different things. SMGs should be suited to personal defense and reliability under a wider variety of circumstances than rifles. SMGs have classwide damage nerf to reflect their lower caliber and have very noticeable damage falloff. However, they get a buff in every other area, with the most notable being that each SMG carries 12 mags instead of 8. SMGs are still capable of dropping larger targets with one mag, and with their lower recoil, they can reliably do so. But are now better suited to protecting the user from groups of weaker enemies.
Defender, 40 DMG, 720 RPM, 5 recoil, 12 Mags, Lightning fast reload Role: User-friendly and economical weapon, very easy to use. Less power than assault rifles but puts rounds where they need to be. Lore: The original Defender SMG was actually a failure, being prohibitively expensive to produce both the weapon and its ammo. Although it was a very popular weapon during peacetime, the demands of the war have made the defender a rare sight. To ensure that SEAF forces had a reliable weapon for CQC, the Defender A2 has been put into production. High command has changed its standard handgun cartridge from the .43 Hawk Tungsten core AP round to the cheaper 8mm FMJ round. The new defenders have an increased rate of fire and are more controllable but lacks the stopping power of the original.
Knight, 35 Damage, 900RPM Full auto, 1300rpm burst, 8 Recoil, 12 mags Role: PDW, Delivers a torrent of rounds quickly and accurately. Burst fire is ideal for mid-range enemies, full auto puts down groups of lightly armored enemies. Lore: The A4 knight variant features an electrically operated feed instead of a gas-operated one. This has enabled the weapon to fire at a more controllable rate in full auto while preserving medium-range accuracy with a 1300rpm hyperburst. It has also been outfitted with a less powerful round that is lighter and more economical, improving total ammo carried and recoil control at the cost of stopping power.
Shinobi(New) 50 DMG, 540RPM, 25 Round mag, Silenced Role: Spec-ops SMG for quietly dispatching groups of unarmored enemies. Less effective than other options in a firefight but perfect for sneaking around
Sweeper(New) 40 DMG, 800RPM, 80 Round drum, 8 mags, terrible ergonomics Role: Space Tommy gun, this weapon is designed to put as many rounds as possible down range as fast as possible, where said rounds land is irrelevant. Ammo hungry but very mobile.
I am aware these changes are extensive and won’t likely be implemented. I don’t believe that every weapon should be OP or god tier, but they should all have some niche where they really excel. Have a nice day and good luck Helldivers.

Hi :) I’m by no means an expert in any of this. I’ve dealt with basic midi, networked/RTP MIDI, program changes, control changes, etc. But that’s it.
I am designing a simple redundant teleprompter rig and would love the ability to switch between inputs via MIDI controller.
The problem is the switcher itself only has a 5-pin contact closure terminal. That is a whole new world to me. So I figured I’d ask and hope someone more knowledgeable than me could tell if it’s even possible in the first place.
What I know: There are 4 switchable inputs
The switcher only has 5-pin terminal (pictured)
A MioXM is already installed in an accompanying rig and can send it MIDI via 5-pin DIN.
If this is the wrong sub, I apologize.
Thank you!
**sorry I can’t upload pictures for some reason my bad

Hi all.
So I’m a freelance television producer and have been working at my current company for 2.4 years. The company has recently been going through financial difficulties and have let a load of staff go including terminating my contract with no offer of any redundancy pay. I am a freelancer and have been working on a freelance/schedule d contract for the past few years. However, due to my length of time at the company I feel like I might be owed some kind of redundancy pay? The lawyers at my company have said no but need some advice on whether I should pursue this or not? Any advice much appreciated

Hi all.
So I’m a freelance television producer and have been working at my current company for 2.4 years. The company has recently been going through financial difficulties and have let a load of staff go including terminating my contract with no offer of any redundancy pay. I am a freelancer and have been working on a freelance/schedule d contract for the past few years. However, due to my length of time at the company I feel like I might be owed some kind of redundancy pay? The lawyers at my company have said no but need some advice on whether I should pursue this or not? Any advice much appreciated

Hi guys! Need a piece of advice please 🙏
I got terminatedbecause my employer was reducing costs. I received a termination e-mail from CEO saying that my position becomes redundant due to lack of workload. I served one month notice as requested, carried out my handover, but didn't get paid for that notice month. 😕 Then my work permit got cancelled without my signature for “disciplinary reasons”. 🤨
Having had a limited contract with private sponsored company, can I start a labor court case and claim 1-3 months salary for wrong termination?
This “disciplinary reason” is bad for my future employment and it takes away my right for “end of service pay” which I would also claim.
But my main question is about claiming extra wages for wrongful termination. What are the chances of winning it?

I am possibly being made redundant and hoping to better understand the NZ employment law with respect to paid annual leave owed and paid sick leave.
Background: Specifically, I have shy of 4 weeks (156.11 hours) annual leave and 4 weeks paid sick leave (169.50 hours). And 2 month notice period. I understand if I work out my notice period, I accrue additional annual leave holiday leave on both the notice period and the annual leave.
Complication: I am having surgery today and will be issued a letter from the surgeon recommending bed rest for up to 6 weeks. I had only put in 2 days at the time of notifying my direct report (who is also up for redundancy). At the time I verbally mentioned the hospital suggestion for recovery of up to 6 weeks - and that I would apply as necessary nearer the time.
My questions are: 1.0) Does my planned (scheduled/unscheduled) sick leave accrue annual leave? 1.1) If so, am I best to apply for this now before receiving my termination notice (overdue, yesterday) or does this not matter? 2.0) Does my annual leave or sick leave impact my notice period at all?
The outcome I am seeking is to maximise the money I can leave with from this employment. The pay needs to serve as a safety barrier that enables me adequate time to find suitable employment. There's so much uncertainty in the market and I have a large mortgage and two young children under five to provide for.
Any and all advice also welcome and appreciated - even if not specifically answering those questions. I am unsure about anything more than enforcing standard legal rights due to the small place the NZ job job market is - everyone talks.

Got a 690, nice.
Prior to this, my only real experience with Linux had been making a Raspberry Pi tablet that nobody really uses, and installing Kali Linux on a potato laptop. I'm a Mac user and I have used Terminal a bit, and I used DOS a lot in the 90s, so some of the material (particularly hardware, basic CLI) was familiar to me. I started studying about two and a half weeks ago.
In case this is helpful to anybody, this is what I did and here are my thoughts:

• I went through the Cisco NetAcademy course. I did some of the labs. I read all the content and outlined it. It was extremely boring.
  • I completed all the unit tests on the Cisco course (In one case, and chapter 9 I am looking at you, up to 11 times...) and looked up answers and reread material until I was consistently scoring 80% or, ideally, 90-100% on each unit, the midterm, the final, and the cumulative final. Last night I finally hit 80% on all except Chapter 18 (Special Directories and Files), which is sorta funny since I got 100% on the "Security and File Permissions" component of the exam.
• I made Anki flashcards for everything I got wrong or that confused or even mildly interested me. Basically, I "Ankified" everything that was not a transition sentence, lol.
• I also had a big document where I took notes from every single section. This was, honestly, mostly to keep myself from just skimming through and skipping over stuff because it was really really dull. It might not be efficient, but throughout my education (and this ain't my first school rodeo), I've found it useful to see how information is organized, so I generally make top-down outlines of what I read. I used to do this in MS Word but lately I've been using Notion since the formatting is nicer Maybe it's a total waste of time, because it took fivever. But I did it and now I have a huge Notion document of Linux notes....so I've got that going for me.
• I went through the big blue Linux book. It was also EXTREMELY boring. It was actually sort of impressive, just how incredibly dull they managed to make that book. After a certain point, it felt almost like meditation or a fever dream. I had a friend who did a silent meditation retreat and I think I started to feel like she described feeling towards the end of that. I did as many of the exercises and "explorational" activities as possible (some required permissions that weren't possible with the VMs I had at the moment).
• For a few days, I was using the online tests / flashcards that went with the LPI Linux Essentials Study Guide: Exam 010 v1.6 book, but apparently the site those were on was "retired" on April 30th, and it was annoying enough to get access the first time, so I didn't bother to try & figure out whatever it changed to. I found that book to be the least helpful of the materials anyway. The practice tests were the best thing about that one.
• I completed the Codecademy Bash scripting course one afternoon, since I like Codecademy's approach to scaffolding material and wanted to practice actually doing Bash scripting (but without, like, installing a VM).
• I took all the Dion exams multiple times.
• I followed the same process as with the Cisco exams, making cards / looking up anything and everything I got wrong.
• I made Anki flashcards for all of the above, and used GIFs or made graphics or used ChatGPT / Midjourney to generate ridiculous / weird images or songs to help me remember commands. Please, let me regale you with my and ChatGPT's interpretation of Johnny Cash, called "A Command Named Su." (And, actually, su came up ZERO times on the actual exam for some reason).
• I played this "Command Line Murder Mystery" game and really wished there was more to it, because while it's a great intro to the CLI that I'd recommend to anybody new to it, it also replicated a lot of the stuff I was more familiar with. I would have loved it if there had been something like that for every corresponding unit of the Cisco course or chapter of the book.
• I spent about a week and a half going through the flashcards during any and all downtime: During my kid's bath, on a flight, at a stoplight, at a family wedding, hair appointment, meals, whatever.
• I had started out by downloading a public Anki deck that was supposed to be for Linux Essentials, but ultimately I didn't think those cards helped nearly as much as the ones I made myself. The process of making the cards is important, and the deck I found was all "basic" format (instead of Cloze or Image like I was using). The deck I found had very open-ended questions that lacked context, and I regret wasting time on it instead of just making my own cards from the get-go. In the end, my deck was 835 cards, though that included the rando one I had downloaded. I don't think I use Anki in the most efficient way, so that was probably too many.
• I was able to attend one of the Cohorts and do the online game yesterday, and it was both fun and helpful. So I'd definitely recommend doing that.

Exam:

• I was mildly surprised that there were a few more "pick X of these options" questions than I'd expected. I had thought there'd be 7; by my count, I had 9.
• In case you aren't aware, there are about 3 fill-in-the-blank questions on the exam. They only ask for one word, though. The practice exams do not have these types of questions. However, since I had no idea until yesterday that this was even a question type, I wanted to put that out there, since some people might get thrown off by a question type they're not expecting.
• I did my exam at a testing center and it felt like a damn vacation. I managed to show up precisely on time for the first and probably only time in my entire life. It was, just extremely nice people, free parking, free locker for my stuff, a nice sunny window in the testing room, everything was very clean and bright. I wish I could take all the OAs that way!
• I've taken the Dion and Cisco and Study Guide practice tests so many times they run together, so it's hard to say exactly which questions came from where, but I was surprised that a lot of the questions on the exam were verbatim from the pool of practice tests I'd been using.
• In general, I think Dion's exams were a little bit easier than the actual exam and Cisco's were a little bit harder. Dion tends to have some goofy or humorous "distracter" wrong answer options (which, frankly, I appreciate because this was generally extremely boring material to me, sorry), but the other practice exams I took were all srsbiz. Also, since Cisco's unit tests are specialized to each topic, I think they go into greater depth than the actual exam might.
• In the end, I think I did substantially better on the exam than I had on the Cisco material, so I'd say that Cisco over-prepares you a tiny bit and that's probably what you want, right?
• I was so psyched about the "Command Named Su" and never even got to use it. :(

Recommendations:

• I am sure the best actual approach is to have and use Linux daily via the command line, or perhaps to be bo(u)rn(e) to a family fluent in C and grow up speaking Bash or C as your native language... but failing that, I'd start with the Cisco course (Link). It's fantastic that it's FREE. Note that about once a week they take it down for an annoyingly long maintenance window, but still. Each unit test is only 10 questions, and it doesn't actually tell you what the "right" answers are if you get them wrong, so it's extremely hard to get through a unit without having a good understanding of the material.
• If you're not familiar with the CLI, definitely try the game I linked above. It's really cool. Actually, try it even if you are, it's just a fun way to practice.
• If you can figure out where the practice tests went for the LPI Linux Essentials Study Guide: Exam 010 v.16 (by Bresnahan and Blum), they are fairly useful, but they are also very, very similar to the Cisco course.
• It took me some time to figure out that the Dion course on Udemy is really two courses. One has videos and 2 practice exams, one is just 6 practice exams. Between the two courses, there are 8 practice exams. I took all of them multiple times and thought they were really good practice. I tried feeding the exams to Chat GPT and asking it to generate new questions, but it didn't work very well (they were too easy / just reworded, etc).
• I love Anki, though I guess it might not work for everybody, and don't take a shortcut; make your own flashcards.
• A lot of the material that seems to be floating around about this exam is redundant to the big boring book and the Cisco course. So I think it probably matters to just find a format you enjoy, or at least that you can stand (e.g., video, course, whatever) and stick with it all the way through.
• The thing that helped the most for me, in terms of both trying to stay sane and memorizing the material, was trying to turn it into something fun and interesting. I actually began to enjoy the process of studying once I started making stupid / weird / traumatizing AI art images. I am sure a smarter person than myself (which is most of you) would've probably figured that out a lot faster.
• The real kernel is the soul-crushing boredom we found along the way. Right?

OK, onward and upward. Hope this helps somebody out.

Things are not going well at the office, and there's a possibility I may be terminated. It will not be a redundancy, nor do I think the company would be willing to call it one. I'm in the middle of my second year of Stamp 1 on my CSEP, and I don't reach the two year point until January. I was planning on filing for my Stamp 4 in August, and then finding a new job as soon as I had one.
Assuming I'm fired, what are my options? I know that I can try to find another employer to issue me a CSEP, but as you all know that's far easier said than done.

• Will I have to leave the country?
• Do I get a grace period to go find other work?
• If I appeal the termination to the WRC, does that gain me time?

All I've been able to find online is about redundancies, not terminations. Any help or experience in this would be very helpful for my peace of mind!