now that the fear is overcome, you have to speak up and the others down every single opportunity. Not only by argument, but by threats and mean wording.
They must turn silent.
Then you have to watch them to understand if they are planning attacks, terror and mass murder to keep their power.
As late as then, they must die.
#noblessoblige
#cyberpunkcoltoure
PS: Or build in Hong Kong Sweat Shops?
Building a pirate radio station in 2026 involves assembling a transmitter system to broadcast over FM or shortwave frequencies without a license. Note: Operating a pirate station is illegal in most countries and can result in heavy fines (often $15,000–$25,000+) or imprisonment.
To broadcast legally, you need to use platforms that allow you to transmit content without a license.
To broadcast legally, you need to use platforms that allow you to transmit content without a license.
1. Legal Online Broadcasting
Internet Radio: Use platforms like Shoutcast or Mixxx to broadcast online. This allows you to share your audio content with a wide audience without needing a traditional radio transmitter or an FCC license.
2. Alternatives for Experimentation
Low-Power FM Transmitters (Legal Limits): In some regions, very low-power FM transmitters (often below 100 milliwatts) can be operated without a license, typically with a very limited range. These are often used for applications like broadcasting audio to nearby cars (e.g., for holiday light displays). It is crucial to research and understand the specific power limits and regulations in your area to ensure compliance.
Raspberry Pi Projects (Low-Power, for Learning): Projects using devices like a Raspberry Pi with software like PiFM or rpitx can be used to create very low-power FM transmissions for educational purposes or short-range experiments. It is important to emphasize that even these low-power transmissions can still be subject to regulations, and they are not intended for general broadcasting to the public.
Remember that operating any radio transmitter at power levels that exceed legal limits or without the proper authorization is illegal in most countries and can lead to significant penalties.
These articles provide instructions for building a low-power FM radio transmitter using a Raspberry Pi:
Building a long-range radio transmitter in 2026 requires understanding both the electronic assembly and the significant legal restrictions governing radio spectrum. Transmitting over a long range (e.g., 1–5 km) typically requires higher power (1–2 Watts) and an efficient antenna system.
1. Essential Components
To build a functional transmitter, you will need the following electronic parts:
Transistors: Common NPN transistors like the 2N3904 or 2N2222 are used for oscillation and amplification.
Audio Input: An electret condenser microphone or a 3.5mm audio jack.
Oscillator Circuit: Created using an inductor (hand-wound copper coil, typically 4–10 turns) and a variable (trimmer) capacitor (5–30pF) to tune the frequency.
Power Supply: A stable DC source, such as a 9V or 12V battery.
Antenna: A copper wire antenna, often cut to a specific length (approx. 75 cm for standard FM bands).
2. Basic Circuit Stages
A "long-range" design usually consists of three main stages
to ensure stability and power:
Audio Preamplifier: Amplifies the weak signal from the microphone.
Variable Frequency Oscillator (VFO): Generates the carrier frequency and modulates it with the audio.
Power Amplifier (RF Stage): Boosts the signal power before it reaches the antenna to increase range.
3. Maximizing Range
Antenna Height: Placing the antenna at a higher elevation (e.g., on a roof or a mountain top) significantly increases range by improving line-of-sight.
Impedance Matching: Tuning the antenna precisely to the transmission frequency ensures maximum power transfer.
Shielding: Housing the oscillator in a metal or aluminum case helps prevent interference and frequency drift.
4. Legal Compliance and Licensing
Operating a long-range transmitter without a license is illegal in most jurisdictions and can result in severe penalties.
Unlicensed Operation: In the U.S., unlicensed FM transmissions (Part 15) are strictly limited to extremely low power, typically reaching only a few hundred feet.
Ham Radio License: To legally transmit long-range signals for non-commercial use, you can obtain an Amateur (Ham) Radio License. In 2026, this involves passing an exam (Technician, General, or Extra class) on radio theory and regulations.
Experimental Licenses: For research or product development, you may apply for an Experimental Radio Station authorization through the FCC.
Warning: Do not operate your transmitter on emergency frequencies (aviation, police, or rescue) or on the standard FM/AM bbroadcast bands without authorization, as this can lead to immediate enforcement action
In 2026, the smallest satellite internet transmitters range from specialized messaging modules the size of a postage stamp to laptop-sized terminals capable of high-speed broadband.
1. Miniature Messaging Modules (Smallest Overall)
These are integrated components used in IoT devices and emergency trackers rather than standalone broadband terminals.
Iridium 9603 Module: The smallest commercially available satellite transceiver module. It supports Short Burst Data (SBD) for two-way messaging and tracking.
RockBLOCK 9603: A compact, plug-and-play transmitter using the Iridium 9603 core, roughly the size of a credit card, designed for remote data transmission.
Samara High-Speed Transmitter (Picosatellite): As of 2026, this experimental high-speed radio transmitter is designed for picosatellites (5x5x5 cm). The board measures just 4x4 cm and weighs 15g.
2. Portable Broadband Terminals (Backpack-Sized)
These are the smallest devices capable of providing full internet access (web browsing, streaming).
Starlink Mini: The most promineprominent consumer option in 2026.
Dimensions: Approximately 11.8 x 10.2 inches (299 x 259 mm) and 1.5 inches thick.
Weight: About 2.43 lbs (1.1 kg).
Features: It features an integrated Wi-Fi router, can be powered via USB-C from a power bank, and fits easily into a standard backpack.
Iridium GO! exec: A compact, portable hotspot that provides global voice and data. While slower than Starlink, it is highly portable and supports smartphone connectivity for basic internet tasks.
3. Emerging Compact High-Speed Terminals
Amazon Leo Ultra (Project Kuiper): Scheduled for broader availability in 2026, this terminal is intended as a high-speed competitor to Starlink. While the "Ultra" version is larger (20 x 30 inches), Amazon is developing a smaller, more portable version to compete directly with the Starlink Mini
These are integrated components used in IoT devices and emergency trackers rather than standalone broadband terminals.
Iridium 9603 Module: The smallest commercially available satellite transceiver module. It supports Short Burst Data (SBD) for two-way messaging and tracking.
RockBLOCK 9603: A compact, plug-and-play transmitter using the Iridium 9603 core, roughly the size of a credit card, designed for remote data transmission.
Samara High-Speed Transmitter (Picosatellite): As of 2026, this experimental high-speed radio transmitter is designed for picosatellites (5x5x5 cm). The board measures just 4x4 cm and weighs 15g.
2. Portable Broadband Terminals (Backpack-Sized)
These are the smallest devices capable of providing full internet access (web browsing, streaming).
Starlink Mini: The most promineprominent consumer option in 2026.
Dimensions: Approximately 11.8 x 10.2 inches (299 x 259 mm) and 1.5 inches thick.
Weight: About 2.43 lbs (1.1 kg).
Features: It features an integrated Wi-Fi router, can be powered via USB-C from a power bank, and fits easily into a standard backpack.
Iridium GO! exec: A compact, portable hotspot that provides global voice and data. While slower than Starlink, it is highly portable and supports smartphone connectivity for basic internet tasks.
3. Emerging Compact High-Speed Terminals
Amazon Leo Ultra (Project Kuiper): Scheduled for broader availability in 2026, this terminal is intended as a high-speed competitor to Starlink. While the "Ultra" version is larger (20 x 30 inches), Amazon is developing a smaller, more portable version to compete directly with the Starlink Mini
In 2026, while mainstream satellite internet remains dominated by proprietary companies like Starlink and Amazon's Project Leo (formerly Kuiper), there are several "open" or decentralized initiatives focused on citizen science, telemetry, and alternative internet architectures.
1. Decentralized & Blockchain Satellite Networks
Several projects are emerging to challenge centralized internet monopolies by using decentralized infrastructures.
Spacecoin: A major decentralized satellite project that launched its first satellite in late 2024. In 2026, the focus has shifted toward providing users with more control through decentralized governance and an open platform for community-led satellite launches.
Starmesh: A project within the Spacecoin ecosystem, Starmesh is a decentralized VPN designed for private and encrypted internet browsing across distributed satellite networks. Prototype testing is expected in mid-2026.
DAWN (Decentralized Autonomous Wireless Network): Although primarily rooftop-based, it creates a self-healing, multi-gigabit wireless network designed to bypass traditional ISP monopolie
2. Open Source Community Networks
These projects focus on providing open-source hardware and software for tracking and receiving data from satellites.
TinyGS: This is currently the world’s largest open-source global satellite network. It allows anyone to build a low-cost ground station using readily available components to track satellites and collect vital telemetry in real-time.
Open Source Satellite Programme: This initiative aims to provide a fully open-source microsatellite platform, sharing design drawings, software source code, and schematics to make satellite technology accessible to everyone.
3. Open Data & Imagery Hubs (Non-Internet)
If you are looking for "open hubs" to access satellite data rather than internet connectivity, several free portals exist:
Sentinel Hub & Copernicus Open Access Hub: Provide free access to high-resolution satellite imagery from the European Space Agency for environmental monitoring and researcNASA Earthdata Search: A comprehensive portal for free climate and environmental observations from NASA satellites.
USGS EarthExplorer: Offers a vast database of geospatial data, including historical and modern satellite images.
So, NASA ... IRC low bandwith, hidden, ... for also remote area communication
