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“Inventing Drones: Uncovering the Exciting World of UAV Technology”

Different from the concept of toy planes and helicopters in the past which could only fly straight or rotate within a certain circle radius. Currently known drones are controlled by radio transmitters, so drones are easier to control and fly. However, more importantly, the inherent stability of drones, combined with advances in camera technology, have made drones a truly unique and superior tool for capturing aerial images and videos never before imagined.

Image from Google

Let’s provide a brief overview of the essential parts of a drone necessary for flight:

1. Frame: The frame is the structure that holds all the components together. It’s typically made of lightweight materials such as carbon fiber, plastic, or aluminum.

2. Motors: Drones usually have four motors, each connected to a propeller. The motors provide the necessary thrust for lift and control.

3. Propellers: Propellers are attached to the motors and generate lift by pushing air downwards. They come in various sizes and configurations depending on the drone’s design.

4. Electronic Speed Controllers (ESCs): ESCs regulate the speed of the motors based on signals received from the flight controller. They control the rotation speed of each motor to adjust the drone’s movement.

5. Flight Controller: The flight controller is like the brain of the drone. It processes data from onboard sensors (like accelerometers and gyroscopes) and user input to stabilize the drone and control its flight.

6. Battery: Drones are powered by rechargeable lithium-polymer (LiPo) batteries. The battery provides the necessary electrical energy to the motors and other electronics.

7. Remote Controller (Transmitter): The transmitter is used by the pilot to send commands to the drone wirelessly. It communicates with the drone’s receiver, allowing the pilot to control flight movements.

8. Receiver: The receiver is onboard the drone and communicates with the transmitter. It receives commands from the pilot and relays them to the flight controller.

The transmitter used for controlling drones is typically a radio transmitter that operates on specific radio frequencies. These transmitters are designed specifically for remotely controlling RC (radio-controlled) devices like drones. Here are some key aspects of transmitters commonly used for drones:

a. Radio Frequency (RF) Bands: Drone transmitters operate on various RF bands, including 2.4 GHz and 5.8 GHz. These frequencies provide reliable communication between the transmitter and the drone.

b. Channels: Transmitters for drones often have multiple channels. Each channel corresponds to a specific control function (e.g., throttle, pitch, roll, yaw) or other features like mode switches.

c. Mode of Operation: Transmitters can operate in different modes such as Mode 1 or Mode 2. In Mode 2 (commonly used for drones), the left stick controls throttle and yaw (rotational movement), while the right stick controls pitch and roll.

d. Transmitter Power: Transmitter power affects the range and reliability of communication with the drone. Higher power transmitters can provide longer ranges, but local regulations may limit the maximum allowable power output.

e. Features and Controls: Drone transmitters often feature trim controls (to adjust the neutral position of controls), dual-rate switches (to change sensitivity of controls), and auxiliary switches for activating different flight modes or features like camera control.

f. Compatibility: Transmitters must be compatible with the drone’s receiver. Some transmitters use specific protocols (like FrSky, FlySky, or Spektrum) that are matched with corresponding receivers installed in the drone.

Popular brands of transmitters used for drones include FrSky, FlySky, Spektrum, Futaba, and others. The choice of transmitter depends on factors like budget, desired features, and compatibility with the drone’s receiver system. When selecting a transmitter, it’s important to ensure compatibility with the drone’s receiver and consider the specific needs of your drone flying activities.

9. GPS Module (Optional): Some drones have GPS modules for navigation and positioning. GPS enables features like autonomous flight, return-to-home, and waypoint navigation.

10.Onboard Camera and Gimbal (Optional): Many drones are equipped with cameras for aerial photography and videography. A gimbal stabilizes the camera to ensure smooth footage.

11. Sensors (e.g., Barometer): Additional sensors such as barometers may be included to assist with altitude hold and overall flight stability.

To fly a drone, you typically assemble these components onto the frame, ensuring everything is securely mounted and connected. Then, you program or configure the flight controller, bind the receiver to the transmitter, and perform a pre-flight check to ensure all systems are functioning correctly. After these steps are completed, you can power on the drone, arm the motors, and begin flying using the remote controller. Always remember to follow local regulations and safety guidelines when operating a drone.

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Hover with Surveillance Camera: Advancing Surveillance Technology

In recent years, the concept of using hover devices equipped with surveillance cameras has gained significant attention in the realm of modern technology. Hover, often referred to as hovering or hovering devices, represents a new frontier in surveillance capabilities, distinct from traditional drones. This article explores what hover is, how it differs from drones, the technological advancements hover brings, its advantages, prominent users, and a comparison of hover versus drone prices.

What is Hover?

Hover, in the context of surveillance technology, refers to unmanned aerial devices capable of hovering or remaining stationary in the air, equipped with cameras and sensors for surveillance purposes. These devices are designed to provide aerial monitoring and reconnaissance without the need for constant motion or flight path adjustments, unlike conventional drones.

Image from Google

Hover vs. Drone: What’s the Difference?

The primary difference between hover and drones lies in their operational characteristics. While drones are often associated with autonomous flight, maneuverability, and varied flight paths, hover devices are engineered for stability and stationary observation. Hovers typically excel in environments requiring steady monitoring and precise surveillance angles.

Modern Technological Advancements of Hover

Hover devices incorporate cutting-edge technology to enhance surveillance capabilities:

  • Stability and Precision: Hovers are engineered for stable hovering, enabling precise and uninterrupted surveillance footage.
  • Silent Operation: Many hover devices prioritize quiet operation, making them suitable for discreet surveillance applications.
  • Advanced Camera Systems: Hovers often feature high-resolution cameras with zoom capabilities, thermal imaging, and night vision for comprehensive monitoring in various conditions.
  • Remote Control and Automation: Modern hover systems offer remote control and automation features, allowing operators to manage surveillance tasks efficiently.

Advantages of Hover for Surveillance

  • Stability: Hover devices offer stable aerial surveillance, ideal for stationary observation tasks.
  • Discretion: Their quiet operation and stationary nature make hovers less conspicuous compared to drones.
  • Precision: Hovers provide precise control over surveillance angles and camera positioning.
  • Versatility: Suitable for indoor and outdoor surveillance, including confined or densely populated areas.

Who Uses Hover and What Departments Benefit?

Hover technology finds applications across various sectors and departments:

  • Law Enforcement: Police departments use hovers for monitoring crowds, traffic surveillance, and tactical operations.
  • Security Services: Private security firms employ hovers for facility monitoring and event security.
  • Emergency Response: Hovers aid in search and rescue operations, disaster assessment, and situational awareness.
  • Infrastructure Inspection: Utility companies utilize hovers for inspecting power lines, pipelines, and other critical infrastructure.

Hover vs. Drone: Price Comparison

The cost of hover devices varies based on specifications, features, and intended use. Generally, hovers designed specifically for surveillance purposes may be priced differently from consumer-grade drones. Hovers tend to prioritize stability, precision, and advanced camera systems, which can influence pricing.

While drones are available in a wide price range, starting from a few hundred dollars for basic models to several thousand dollars for professional-grade options, hover devices tailored for surveillance purposes may fall within a comparable pricing spectrum.

Conclusion

Hover with surveillance cameras represents a significant advancement in aerial surveillance technology, offering stability, precision, and discretion for various monitoring applications. With their innovative features and distinct operational characteristics, hovers complement traditional drones and cater to specific surveillance needs across industries.

In summary, hover devices are reshaping the landscape of aerial surveillance with their unique capabilities, attracting interest from law enforcement, security services, emergency responders, and infrastructure inspectors alike.

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A pivotal development in the evolution of UAV

Military Origins

The integration of cameras with drones has been a pivotal development in the evolution of UAV (unmanned aerial vehicle) technology, enabling applications ranging from aerial photography and videography to surveillance and mapping. The initial integration of cameras with drones occurred primarily for military reconnaissance purposes but has since evolved to cater to consumer and commercial needs.

In the early stages of drone development, cameras were integrated with UAVs primarily for military reconnaissance missions. During the Vietnam War in the 1960s and 1970s, drones equipped with film cameras were used by the United States for surveillance operations over enemy territory. These early drones were operated remotely and provided real-time visual intelligence to military personnel.

Analog Camera Integration

The first cameras integrated with drones were typically analog systems, including film cameras and early video cameras. These cameras were mounted on drones to capture still images or video footage during flight. The recorded footage was often used for intelligence gathering, target acquisition, and situational awareness in military operations.

Advancements in Digital Imaging

The evolution of digital imaging technology played a crucial role in enhancing the capabilities of cameras integrated with drones. As digital cameras became more compact, lightweight, and capable of capturing high-resolution images and videos, they became ideal for UAV applications. Digital cameras offered advantages such as instant image review, easy storage of captured data, and improved image quality compared to analog systems.

Commercial and Consumer Adoption

The integration of cameras with drones for civilian and commercial use accelerated in the early 2000s. Companies like DJI and Parrot pioneered consumer-grade drones equipped with built-in cameras designed for aerial photography and videography. These drones were equipped with stabilized gimbals to ensure smooth footage and high-quality imaging.

Gimbal Stabilization Technology

One of the key advancements that facilitated the integration of cameras with drones was the development of gimbal stabilization technology. Gimbals are mechanical devices that enable a camera to remain stable and level despite the motion of the drone. This technology is crucial for capturing professional-quality aerial footage without the jitters or vibrations typically associated with drone movement.

Integration Challenges and Solutions

Integrating cameras with drones posed several challenges, including weight limitations, power consumption, and data transmission. Drone manufacturers addressed these challenges by optimizing camera designs for lightweight and efficient operation, developing advanced imaging sensors, and implementing wireless transmission technologies to stream live video feeds from drones to ground stations or mobile devices.

Current State of Camera Integration

Today, drones are equipped with sophisticated cameras capable of capturing high-resolution photos and videos in various environmental conditions. Advanced features such as optical zoom, thermal imaging, and multispectral imaging have expanded the capabilities of drone-mounted cameras, enabling applications in agriculture, environmental monitoring, search and rescue, and more.

In summary, the integration of cameras with drones has evolved from its military origins to become a ubiquitous feature in consumer and commercial UAVs. The development of digital imaging technology, gimbal stabilization, and optimized camera designs has transformed drones into powerful tools for aerial photography, cinematography, and data acquisition across diverse industries.

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Outdoor Surveillance Camera

caught by surveillance camera
Source Image : Cnet

Technology that accompanies surveillance cameras

At first surveillance cameras or whatever was used for surveillance and observing the environment, the main purpose was for security. In recent decades the cameras mentioned above have expanded their use not just as “surveillance” tools but surveillance for purposes other than security.

Until now, security purposes still occupy the top position in the use of this surveillance camera. Better known as CCTV (Close Circuit Television) is widely installed in private homes, housing complexes, office buildings, public facilities, highways, government agencies, and military agencies. The location of this camera placement can be installed outdoors or indoors.

Commercial-Grade Security Cameras vs. Consumer-grade.

The sale of surveillance cameras that are widely offered is Consumer-grade because of the wide range of enthusiasts and users besides that the prices are affordable. The package offers consumer-grade types consisting of 6 to 16 cameras equipped with video recorder capabilities.

Meanwhile, a commercial grade is set at a higher price, because its capabilities are superior to those of consumer grade. The advantages of commercial grade include greater data storage capabilities than a greater number of camera connections and also feature image processing or the ability to process image data.

Commercial-grade design and built to produce high-level capabilities and is claimed to be fail-safe, and can operate in a variety of varying lighting levels.

In general, consumer-grade CCTV can only work properly if the area around the camera range has enough light.

This is not the case with commercial-grade CCTV cameras that have the ability to work more precisely, this is because commercial-grade devices are equipped with internal video sensors.

Commercial-grade cameras have the ability to adapt and work in minimalist lighting, this is because of the internal video sensor. This device is also equipped with software and hardware called HDR (High Dynamic Range) which allows the camera to adapt quickly to changes in lighting.

Even though consumer-grade CCTV cameras can actually work in insufficient lighting, the resulting image quality is less clear.

This is due to the device taking time to adapt to the light, with extra light being let into the room by opening the shutter to compensate.

In addition to the built-in video sensor and HDR software/hardware, this commercial grade is also equipped with an “intelligent IR” (infrared) night vision illuminator that has the ability to adjust exposure. With smart IR this device can record objects in more detail even in low light or dark conditions.

The development of internet technology has brought new changes to the security system which was previously carried out by CCTV independently. Advances in technology have changed the game, the problem of previous CCTV owners was that the data storage devices were damaged for some reason or lost due to theft. Damage to or loss of data recorders leads to evidence of wrongdoing or crime without proof. Without evidence, it is impossible to catch or imprison the perpetrators of crimes.

However, technology has overcome this problem by developing a system called the “Intelligent Security System”, this system works by connecting all security systems including CCTV camera devices to the internet network.

With this system, all data captured by the attached camera is sent directly to and stored in “cloud storage” as data backup storage.

So far, the Intelligent Security System mode is considered the safest and most efficient because apart from cloud storage being separate from the main CCTV device, the cloud also has the ability to store unlimited data.

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Drones in various applications

November 8, 1898, Nicolas Tesla, US inventor of Serbian descent patented the remote control or remote control of his findings. This remote control became the basis of contemporary robotics. Tesla built ships and balloons that could be controlled remotely. Starting from Tesla’s findings, slowly but surely the development of root vehicles continues to grow. The next scientist continued the existing research to give birth to the various types of robotic vehicles that we know today, starting with drones, then ROVs for water applications, especially seas and UGVs for land vehicles.
What are drones
The drone we are referring to here is the UAV (Unmanned Aerial Vichicle) which is widely used in the military world. The name drone is a popular term attached to this remotely controlled robotic aircraft. Drone because of the sound it makes resembles a drone (drone). The drone’s ability to fly with remote control is due to Software-Controlled Flight which is connected to the Onboard Censors and GPS system embedded in the drone.

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Modern Watches are not Just a Timepiece.

Source image : digitaltrends.com

Modern Watches are not Just a Timepiece.

1812, Abraham-Louis Breguet designed the first wristwatch for Queen Caroline Murat, sister of Napoleon Bonaparte. This watch, made by Breguet, is equipped with a strap that attaches to the Queen’s wrist.

The brand name is taken from its founder, Abraham-Louis Breguet who was born in Neuchatel, Switzerland, on January 10, 1747.

In 1926 the automatic watch changed all this forever with the addition of a driven rotor that re-tightened the spring with the natural movement of the wearer’s hand.

This invention was followed by a second revolution in 1969 in the manufacture of the first quartz watch.

In 1972, Hamilton introduced the world’s first commercial electronic digital wristwatch which was followed by SEIKO’s introduction of the world’s first six-digit LCD quartz wristwatch with code 0614 in 1973.

In 1998, Steve Mann invented, designed, and built the world’s first Linux watch. The scope of this wristwatch project includes planning, design, development, testing, and then product release. His product was presented at IEEE ISSCC2000 on February 7, 2000, at which time he was named the “father of wearable computing”.

The first generation of Sony Smart Watch design was released in 2012. Sony smart watch is a line of devices developed and marketed by Sony Mobile until 2016 through three generations. They are connected to the Android OS. The features of this watch include displaying information such as Twitter features and SMS messages.

Then in April 2015 Apple, the world’s largest technology company, released its long-awaited smartwatch. It has much more detailed functionality that approaches the smartphones you see today, including mobile apps, mobile operating systems, and WiFi/Bluetooth connectivity.

Some smartwatches function as portable media players, with FM radio and playback of digital audio and video files via a Bluetooth headset. Some models, called watch phones (or watch phones), have cellular functions such as making phone calls.

In essence, a smartwatch is a wearable computer in the form of a wristwatch. Modern smartwatches provide local touchscreen interfaces for everyday use, while their health-related smartphone apps provide telemetry management and biomonitoring.

Like computers, smartwatches can gather information from internal or external sensors and can control, or retrieve data from, other instruments or computers. It is possible that smartwatches already support wireless technologies such as Bluetooth, Wi-Fi and GPS.

For many purposes, a “watch computer” serves as the front end for a remote system such as a smartphone, communicating with the smartphone using a variety of wireless technologies.

In recent times, smartwatches have seen advances in design, battery capacity, and health-related applications including heart rate, SpO2, and other sports-related health features.

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Smartphone at a glance

SMARTHONE
Source Image : T3.com

Smartphones as Modern Phones

The smartphone that we use today is a communication device whose existence has spread widely throughout the world. It can be said that every household on this earth has at least one smartphone unit. Without research, we all understand how popular smartphones are today. Try to pay attention to how many units of smartphones are in your house, and also pay attention to your left and right neighbors.

The spread and use of this communication tool is so fast and large, this is partly due to the tendency of the internet-based digital world in almost all fields and human activities.

 Judging from its history, smartphones do not necessarily come with the form and function as they are now, but have gone through a long process and development, starting from a pioneer cellphone to the form it is today with various features and technology embedded in it.

 It all started with the cellular invention pioneered and developed by an American company, it was first designed in1940,  but the invention was never put into production. In1973 Martin Cooper designed a truly portable cell phone. From Cooper’s design, then continued to the production level by US cell phone manufacturer Motorola, the mobile phone produced was codenamed Dyna TAC, which is a cell phone production from the first generation.

As is well known, a cell phone is a portable telephone unit that can send and receive telephone calls or short messages via radio frequency as long as the user is within its coverage area. The radio frequency is then processed by the cell phone operator’s MSC (mobile switching center) system so that the frequency signal can be accessed by the PSTN (public switched telephone network).

 Why are handphones called “cellular”, the network where the handphone frequency operates is in the form of blocks with an area of 26 Km square, and each of these blocks consists of several hexagonal cells, the number of cells in each block ranges from 7 to 12 cells. Between one cell and other cells are interconnected so that it resembles the structure of cell tissue.

Each network cell is represented by a BTS (base transceiver station).

 Cell phones that previously only had 2 features, namely sending and receiving phone calls and short messages, have now become digital phones equipped with various new features besides the old features that are still being maintained. New features that are planted include multimedia messaging, internet access, email.

Short-range wireless access is also increasing, apart from infrared and Bluetooth it is also equipped with Wi-Fi.

 The embryo of the world’s first smartphone was created in 1992 by a technology company from the United States, IBM.

 The world’s first smartphone was called Simon Personal Communicator (SPC). Starting from zero G, 1G, and in 2001 the first smartphone that supported a 2G network connection was born. 2007 was a milestone in the history of the smartphone industry, namely since the release of the iPhone by Apple with a 3G network connection.

 Communication satellites have also become standard equipment for navigation and communication connections, video game features and digital photography are also embedded in modern mobile phones. With the ability to match a laptop, the device is called a smartphone.

 The transmission system that accompanied the first generation of mobile telephones was called GSM (Global System for Mobile Communication). GSM including CDMA works on 2G networks while the next generation UMTS and CDMA2000 work on 3G networks.

The next generation, namely Smartphones, uses the LTE (Long Term Evolution) transmission system which works in the 4G network which is a combination and development of the two 2G and 3G technologies above.

 Among the three (2G, 3G and 4G) there are capacity specifications and data transmission speeds that differ from one to another, each of which is influenced by the accompanying hardware, software and systems.

 Some of the things that distinguish between Cell Phone Cars and Smartphones are:

 Cellular Connection :

Wireless connection using GSM cellular network protocol. Accommodates voice and data calls.

 Smartphone connection:

LTE connection Accommodates for high speed data communication.

 Cellular frequency :

Frequency Division Multiple Access (FDMA) and Time-division (TDMA).

 Smartphone frequency :

Orthogonal frequency division multiple access(OFDMA) and Single-carrier frequency division multiple access(SC-FDMA)

 Cellulr communication standard :

2G and 3G communication standards.

 Smartphone communication standard:

Using fourth generation 4G.

 Cellular operating base:

Works in 900 MHz and 1800 Mhz frequencies.

 Base operating smartphone:

The frequencies from 1 to 25 and from 33 to 41 are reserved for FDD (Frequency Division Duplex) and TDD (Time Division Duplex) respectively.

 Cellular information channel :

Information is transmitted through channels that are separated into physical and logical channels.

Smartphone information channel :

Information is carried using physical, logical, and transportation channels.

 Cellular Sim card :

Customer information is stored in the Sim card.

Smartphone Sim Card :

Sim card is required to verify the customer’s cell phone.

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A brief note on the development of drones

Drone flying over the night city
Source Image : istockphoto.com

Drones from time to time

 The drones we know today result from a long journey of research and development by engineers in several European countries. At first, people were motivated to create unmanned flying machines for military needs and to win wars. In the future, UAVs were not only to meet the demands of the military but also for the interests of non-military and drone enthusiasts.

The recorded history of making UAVs is mostly located in mainland Europe, starting from Austria.
1849, the concept of drones began in Austria when they attacked Venice using an unmanned balloon stuffed with explosive material.

In 1907, Jacques and Louis Breguet, helped Charles Richet develop a quadcopter configurated equipped with a gyroplane.

In 1916, British engineer Archibald Low developed pilotless aircraft called Ruston Protector Aerial Target which used a radio guidance system.

1918, Kettering Bug an aerial torpedo built by Us Aemy, this torpedo used gyroscopic control. The four-wheeled dolly used to launch that rolled down a portable track.

To stop the torpedo enginee the system is still very simple compared to the aircraft system, namely the electrical circuit control shut off the engine causing the torpedo to plunge into the earth.

1930, a radio control aircraft called Curtis N2C-2 was built by US Navy, this model was the first experimenting radio control aircraft.

In 1935, British Army developed a drone called Queeb Bee as a radio control manned aircraft

1943, German adopted Queen Bee and began to build V-1 (Vergeltungswaffen), a missile an unmanned device equipped with a magnetic compass, and barometric used to control altitude. Gyros, rudder, and elevator are controlled using pressurized air.

In 1950, US Army built the unmanned spy plane called SR-71 Blackbird, which was meant to gather information in combat areas. Later the SR-71 was updated with the next model Ryan 147B.
To obtain the information collected, the plane must be landed using a parachute.

1980 – 1986 Joint project between USA and Israel developed an inexpensive medium size reconnaissance UAV, the project-built model RQ2 Pioneer UAV.

In 1989, Micro and mini UAVs were introduced the famous one was the Predator. Predator successfully carried out its mission in the war in Afghanistan.

After the success of the predator, it continued with the birth of the latest generation of mini UAVs, including Raven, Wasp, and Puma developed by AeroVironment Inc.

The last 10 years have seen there was a tremendous surge in demand, especially drones for military purposes, agricultural interests, and for hobbyists

Currently, there are drones with various types, functions, and sizes, including:

Currently, several countries that have drone manufacturing industries include:

Multi-rotor drones and their function in Aerial photography, Aerial inspection, Landing surveying, and Agriculture.

Fixed-wing drones and their function in Aerial mapping, Utility inspection, Surveillance, and Agriculture.

Single-rotor helicopter drones and their function as Aerial LiDAR laser scanning.

Fixed-wing hybrid VTOL drones and their functions such as Aerial mapping, Utility inspection, Surveillance, agriculture, Search and rescue.
Several countries that have industry manufacturing drones are the USA, Russia, Turkis, Israel, Azerbaijan, Taiwan, China, Egypt, Ethiopia, France, India, Indonesia, and many more.

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Digital Technology

Source Image : dreamstime.com

Digital Technology Transformation.

Since the beginning of the idea until now, approximately 80 years of history have been achieved by digital technology, digital technology, when it was popularly known as computer science. During which time this technology has penetrated into various sectors of human life.
As a change in technological development, today digital technology is popularly known as the G-4 phase. Various equipment ranging from equipment that is used daily to sensitive military technology cannot be separated from Digital Technology. However, digital technology is a development that existed before, namely analog technology.

Digital Definition

The word “digital” comes from Latin – digitus, finger – and refers to one of the oldest tools for counting. When information is stored, transmitted or forwarded in digital format, it is converted into numbers binary – at the most basic machine-level as “zeroes and ones.” processed by microprocessors.

According to programminginsider.com

Digital technology refers to electronic tools, devices and systems that process, transmit and store data in binary form. Unlike analog technology, which carries data in wave length signals, digital technology encodes data as true or false, on or off.

According to Forbes, digitization is taking analog information and encoding it into zeros and ones (binary language) so that computers can store, process, and transmit that information.

The digital technology that we enjoy now is the result of a stage-by-step development carried out by experts. In short, the development of computer technology, In short, the development of computer technology, mathematics, physics, and principles of engineering also electro is closely related to the development of digital technology, as adapted from Wikipedia, as follows: and electro technology is closely related to the development of digital technology, as adapted from Wikipedia, as follows:

1947–1969: Origins
1947, the first working of transistor, the Germanium based point contact transistor, was invented by John Bardeen and Walter Houser Brattain while working under William Sockley at BELL Labs, this led the way to more advanced digital computer.

1969–1989: Invention of the Internet, a rise of home computers

The public was first introduced to the concepts that led to the internet when a message was succeed sent throgh the Arpanet in 1969. Networks such as ARPANET, were developed in the late 1960s and early 1970s using a variety of protocols. The ARPANET in particular led to the development of protocols for internetworking, in which multiple separate networks could be joined into a network of networks.

1989–2005: Invention of the World Wide Web

Mainstreaming of the Internet,Web 1.0 in this time Tim Berners – Lee (1989) invented the World Wide Web.

2005 – present:

Web 2.0, social media, Smartphone, Digital Terrestrial television, Video game, Video game console.