Jumat, 19 Februari 2021

Come Back to e_SWEETY ( electronic energy function to all system ) ; Transformer ( AC to AC ) ___ Adapter ( AC to DC )___Converter( DC to DC ) ___Inverter(AC to DC) : All systems on earth require these four forms of energy conversion, especially to run: airplanes, satellites, ships, modern vehicle equipment and smart homes, smart factories and smart phones __ AMNIMARJESLOW GOVERNMENT 2033 ANSEL or ANCELL 030410 __ O*** Gen. Mac Tech and O****x_Gen. CID Star Gate -- at Stability

At a time when the 20th and 21st centuries, energy sources are a runway to increase the degree of human life on earth, there is a lot that needs to be considered and upgraded in this life, especially in the field of discovery of renewable electronic materials and research and design in outer space as well as on other planets. which is several light years from earth. at this time the technology is still based on the engineering technology of the source source of the transformer, analog and digital adapters, converters, inverters. which of course in the future we must be able to continue to the form of electronic energy with materials and systems that are increasingly developing from electronic energy that we will discuss today. Welcome to e_SWEETY ( Study__Work__Easy__Energy__Transform__You )
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The basic functions of importance for power electronics are (1) power conversion, ac to dc, dc to ac, ac to ac, (2) power conditioning to remove distortion, harmonics, voltage dips and overvoltages, (3) high speed and/or frequent control of electrical parameters such as currents, voltage impedance, and phase angle, efficiency energy transform .
________________________________________________________________________________________________________________________________________________ Some examples of uses for power electronic systems are DC/DC converters used in many mobile devices, such as cell phones or PDAs, and AC/DC converters in computers and televisions. Large scale power electronics are used to control hundreds of megawatt of power flow across our nation. ** TRANSFORMER ___________ A transformer is a passive electrical device that transfers electrical energy from one electrical circuit to another, or multiple circuits. A varying current in any one coil of the transformer produces a varying magnetic flux in the transformer's core, which induces a varying electromotive force across any other coils wound around the same core. Electrical energy can be transferred between separate coils without a metallic (conductive) connection between the two circuits. Transformers are most commonly used for increasing low AC voltages at high current (a step-up transformer) or decreasing high AC voltages at low current (a step-down transformer) in electric power applications, and for coupling the stages of signal-processing circuits. Transformers can also be used for isolation, where the voltage in equals the voltage out, with separate coils not electrically bonded to one another. Transformer look like traffic on round 🚔 circle , lets look example 🔓⛽
Since the invention of the first constant-potential transformer in 1885, transformers have become essential for the transmission, distribution, and utilization of alternating current electric power.A wide range of transformer designs is encountered in electronic and electric power applications. Transformers range in size from RF transformers less than a cubic centimeter in volume, to units weighing hundreds of tons used to interconnect the power grid. Various specific electrical application designs require a variety of transformer types. Although they all share the basic characteristic transformer principles, they are customized in construction or electrical properties for certain installation requirements or circuit conditions. In electric power transmission, transformers allow transmission of electric power at high voltages, which reduces the loss due to heating of the wires. This allows generating plants to be located economically at a distance from electrical consumers. All but a tiny fraction of the world's electrical power has passed through a series of transformers by the time it reaches the consumer. In many electronic devices, a transformer is used to convert voltage from the distribution wiring to convenient values for the circuit requirements, either directly at the power line frequency or through a switch mode power supply. Signal and audio transformers are used to couple stages of amplifiers and to match devices such as microphones and record players to the input of amplifiers. Audio transformers allowed telephone circuits to carry on a two-way conversation over a single pair of wires. A balun transformer converts a signal that is referenced to ground to a signal that has balanced voltages to ground, such as between external cables and internal circuits. Isolation transformers prevent leakage of current into the secondary circuit and are used in medical equipment and at construction sites. Resonant transformers are used for coupling between stages of radio receivers, or in high-voltage Tesla coils.
________________________________________________________________________________________________________________________________________________ **** ADAPTER _________ An adapter or adaptor is a device that converts attributes of one electrical device or system to those of an otherwise incompatible device or system. Some modify power or signal attributes, while others merely adapt the physical form of one connector to another. 1. adapter in its internal style guide, namely, use adaptor when referring to devices and adapter when referring to people. 1 : one that adapts. 2a : a device for connecting two parts (as of different diameters) of an apparatus. b : an attachment for adapting apparatus for uses not originally intended. How it works. A simple AC adapter consists of a transformer, a rectifier, and an electronic filter. The transformer initially converts a relatively high-voltage alternating current that is supplied by an electrical outlet to a lower voltage suitable for the device being powered.An adapter card (also known as an expansion card) is simply a circuit board you install into a computer to increase the capabilities of that computer. They are large because of the physical size of the components that they need. With newer technology, and lower power devices, some AC adapters no longer do that, but for larger devices that is likely to be an issue for years to come. One solution is to use a cable extension between the AC outlet and the adaptor . 2. A SanDisk adapter is a PC card you insert into your laptop that lets you transfer data between devices such as phones. The SanDisk adapter lets you insert the phone's memory card to transfer data. AC-to-DC adapters A "power cube"-type AC adapter An AC-to-DC power supply adapts electricity from household mains voltage (either 120 or 230 volts AC) to low-voltage DC suitable for powering consumer electronics. Small, detached power supplies for consumer electronics are called AC adapters, or variously power bricks, wall warts, or chargers. Computer adapters A host controller connects a computer to a peripheral device, such as a storage device, network, or human interface device. As a host controller can also be viewed as bridging the protocols used on the buses between peripheral and computer, and internally to the computer, it is also called a host bus adapter. Likewise, specific types may be called adapters: a network interface controller may be called a network adapter, and a graphics card a display adapter. Adapters for external ports Adapters (sometimes called dongles) allow connecting a peripheral device with one plug to a different jack on the computer. They are often used to connect modern devices to a legacy port on an old system, or legacy devices to a modern port. Such adapters may be entirely passive, or contain active circuitry. A common type is a USB adapter. One kind of serial port adapter enables connections between 25-contact and nine-contact connectors,[2] but does not affect electrical power- and signalling-related attributes.
_______________________________________________________________________________________________________________________________________________ ****** CONVERTER Electronics _____________________ Converters and inverters are electrical devices that convert current. Converters convert the voltage of an electric device, usually alternating current (AC) to direct current (DC). On the other hand, inverters convert direct current (DC) to alternating current (AC). 4-Different Power Converters Introduction to Power Electronic Converters. AC to DC Converters or Rectifiers. Uncontrolled Diode Rectifiers. Single phase half-wave rectifier. ... DC to DC Converters. Step-down Chopper or Buck converter. Step-up Chopper or Boost converter. ... AC to AC Converters. AC/AC Voltage Converters. ... DC to AC Converters or Inverters. These converters are used to regulate and shape an electrical signal in the required form. Among these converters, AC–DC converters, commonly known as rectifiers, are used extensively in renewable energy systems such as grid-connected DC microgrids, grid-connected solar photovoltaic energy conversion systems, etc. Some examples of uses for power electronic systems are DC/DC converters used in many mobile devices, such as cell phones or PDAs, and AC/DC converters in computers and televisions. Large scale power electronics are used to control hundreds of megawatt of power flow across our nation. The big difference between an adapter and a converter is electricity. While the purpose of an adapter is to simply help the plugs on your electronics fit into (or more aptly, adapt to the shape of) foreign outlets, a converter's job is to change the voltage found in an outlet to match that of your devices. There are three major kinds of power supplies: unregulated (also called brute force), linear regulated, and switching. Many common persovonal devices--like an iPhone charger, laptops, and cameras--that people like to travel with can be easily powered up abroad with a simple plug adapter because they are dual voltage devices. Plug adapters do not convert electricity; converters do that, but you won't need one for a dual voltage device. iPhone's charger works both on 120 volt and 220 volt. ... A plug adaptor is all you need, the charger itself can run on any voltage between 100 and 240. Full converter : In the same circuit as above uses 4 thyristors (which is like a diode which turns on only when an external signal is given by us) So that we can control the output voltage of the converter dc output. Semi converter : In the same circuit , 2 thyristors and 2 diodes are used. Power electronics is the application of solid-state electronics to control and convert one form of electrical power to another form such as converting between AC and DC or changing the magnitude and phase of voltage and current or frequency or combination of these. Power electronics converters are widely used in myriad power conversion applications from fraction of volt and power to tens of thousands of volts and power levels. Sometimes it involves multistage power conversion with two or more converters connected in series/parallel or in cascade fashion. The application might be different, but the end goal is primarily driven by five major aspects, such as: energy efficiency, power density, cost, complexity, and reliability, which also influence each other to some extent. In this chapter, various power electronic convertors (AC-DC, DC-AC, DC-DC, and AC-AC) and commonly used circuit and topologies are introduced with their general operating principle.
compare to Human Body Convert Signal ____________________________________
Compare to Electronic Automotive __________________________________
________________________________________________________________________________________________________________________________________________ ********* INVERTER ________ A power inverter, or inverter, is a power electronic device or circuitry that changes direct current (DC) to alternating current (AC). ... The input voltage, output voltage and frequency, and overall power handling depend on the design of the specific device or circuitry. A device that converts direct current electricity to alternating current either for stand-alone systems or to supply power to an electricity grid. An inverter is energy saving technology that eliminates wasted operation in air conditioners by efficiently controlling motor speed. ... In inverter type air conditioners, temperature is adjusted by changing motor speed without turning the motor ON and OFF. According to the output characteristic of an inverter, there can be three different types of inverters. Square Wave Inverter. Sine Wave Inverter. Modified Sine Wave Inverter. The applications areas of inverters such as: Adjustable-speed ac motor drives. Uninterrupted power supplies (UPS) Running appliances of ac used in an automobile battery. power transmission industry such as reactive power controllers and adaptive power filters.
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Jumat, 15 Januari 2021

Hello !! Welcome to electronics RF Signal conditioner is something that is connected in the range and space for the development of 4-dimensional commands in a short software system and simple hardware for the purpose of brainware, electronic machines that can make decisions and think according to the intended target with 1000 percent precision and accuracy as like as Rainbow frequency Windows __ AMNIMARJESLOW GOVERNMENT Link gate __ STAR to Windows Gate .

DREAM INSPIRE CREATION MOMENT ACTION AND REACTION THE PLACE TO PRO LIFE , PRO LIVE AND PRO FUTURE LIVING IN LORD WE HAVE GOT THE HAPPY PLACE Sign In ;1. Gen . CID STAR TIME GATE 2. Gen . Mac Tech __________________________________________________________________________________________________________________________
A radio frequency power amplifier (RF power amplifier) is a type of electronic amplifier that converts a low-power radio-frequency signal into a higher power signal. Typically, RF power amplifiers drive the antenna of a transmitter. In radio transmission, transmitter power output (TPO) is the actual amount of power (in watts) of radio frequency (RF) energy that a transmitter produces at its output. ... The radio antenna's design "focuses" the signal toward the horizon, creating gain and increasing the ERP. example of RF we look at RF transistors are designed to handle high-power radio frequency (RF) signals in devices such as: ... Radio transmitters. Television monitors. RF signals and measure a wide range of signal parameters. ... the capability to measure input and output power on a device, circuit, or system and compute a gain or loss. RF travel make For a 2.4 GHz transmission path to transmit 5 miles, you would need antennas at 9.6 m (31 ft). For 900 MHz at 20 miles (32 km), you would need antennas of at least 46 m (152 ft) to achieve a good signal. In many practical settings, your transceivers may function with a lower antenna height, but the higher the better. The Received Signal Strength Indicator (RSSI) measures the amount of power present in a radio signal. It is an approximate value for signal strength received on an antenna. Measuring the signal strength at the receiving antenna is one way to determine the quality of a communication link. ... The RSSI is measured in dBm. A tuned amplifier that amplifies the signals commonly used in radio communications. Amplifier designs in the radio-frequency (RF) range differ significantly from conventional low-frequency circuit approaches; they consequently require special, distributed circuit considerations. In telecommunications, particularly in radio frequency, signal strength (also referred to as field strength) refers to the transmitter power output as received by a reference antenna at a distance from the transmitting antenna.
The main element of RF sensors based on diode detectors is that it uses diode rectifiers in order to produce an output. The RF power sensors using these diodes make it possible for RF power to get dissipated in a load. The detector then rectifies the voltage signal that appears across the load. RF in wireless communication : RF signals are easily generated, ranging 3kHz to 300GHz. These are used in wireless communication because of their property to penetrate through objects and t ravel long distances. Radio communication depends on the wavelength, transmitter power, receiver quality, type, size and height of the antenna. There are basically three different types of wireless networks – WAN, LAN and PAN: Wireless Wide Area Networks (WWAN): WWANs are created through the use of mobile phone signals typically provided and maintained by specific mobile phone (cellular) service providers. RF detectors really work? Bug detectors, though slightly more complex than camera detectors, are fairly simple to use. Since bugs transmit RF (radio frequency) signals, bug detectors hone in on those signals and indicate that there is a bug present, by lighting up, making a sound, or both . RF detector detect ; A radio frequency (RF) detector is a device used to detect the presence of RF waves either in a wireless or wired (on RF Cable) physical transmission medium. They are also known as RF power detectors or RF responding detectors and are available as devices or modules. Hidden camera detector ; Hidden Camera Detector Professional detectors offer two methods of finding a camera: either they look for that glint from the lens (much like using a flashlight or smartphone), or they detect RF broadcasts from a wireless camera. ... A camera lens should light up in the detector's viewfinder, making it easy to spot. Listening Device Detectors ; A radiofrequency detector can scan for transmitters. Turn off all wireless devices, including smartphones and routers, then slowly and carefully move the bug detector around your home. Anything that's broadcasting a radio signal will be found.
RF power amplifier __________________ A radio frequency power amplifier (RF power amplifier) is a type of electronic amplifier that converts a low-power radio-frequency signal into a higher power signal. Typically, RF power amplifiers drive the antenna of a transmitter. Design goals often include gain, power output, bandwidth, power efficiency, linearity (low signal compression at rated output), input and output impedance matching, and heat dissipation. The basic applications of the RF power amplifier include driving to another high power source, driving a transmitting antenna and exciting microwave cavity resonators. Among these applications, driving transmitter antennas is most well known. The transmitter–receivers are used not only for voice and data communication but also for weather sensing (in the form of a radar). RF power amplifiers using LDMOS (laterally diffused MOSFET) are the most widely used power semiconductor devices in wireless telecommunication networks, particularly mobile networks. LDMOS-based RF power amplifiers are widely used in digital mobile networks such as 2G, 3G, and 4G. Concepts of RF Power Amplification ___________________________________ Introduction RF Power Amplifier design is a complicated task, which very often involves a team of engineers working on its different aspects (system design, circuit implementation and testing, mechanical design, control circuitry – to name a few). In order to synchronize their efforts, all team members have to have a clear understanding of the common goals and methods of their solution. These notes describe basic amplifier requirements, mention approaches for meeting them, and briefly discuss a design flow. To keep them useful for all team members (regardless of their specialty or experience), formulas were avoided in the text and just a few of them are given in the appendix. For the same reason references were deliberately omitted: those who are interested in them can Google the subject or request them from the author.
Power Amplifier Requirements The RF Power Amplifier (PA) is the last component of a transmitter chain. The purpose of a transmitter is to deliver an RF signal with required properties and specified power level to the antenna; and the need for the PA is in amplification of that signal to the level expected at antenna port. That is, in order to do the job, the PA has to meet the following requirements: It has to have sufficient Gain – to amplify RF signal to the level expected at Antenna Port. It is expressed as the difference between input and output RF powers. It has to have sufficient Power Handling Capability – to be able to sustain a RF power level expected by the Antenna Port. Sometimes it is expressed as “dissipated power”, however for high power RF transistors it is often given as “Saturated Power” level. It has to be distortion-free – in order for a system’s receiver to be able to recognize radiated signal. It is expressed as a degree of linearity. It has to be stable – to avoid a creation of oscillations over anticipated variations of external conditions (that is, changes in temperature, load, frequency, DC and RF powers) In addition, it is preferable that PA requirements are to be met efficiently. It is needed to avoid wasting of DC power, and/or to preserve the battery drainage. The problem with efficient amplifiers though, is that they do introduce additional distortions which increase with increasing efficiency. In order to deal with this issue, a number of linearization techniques have been developed. Amplifiers are divided into different classes (Class A to C for controlled current source and Class D and above for switched mode amplifiers) and linearization, specific for a given class, is applied. All these requirements have to be met over the frequency band of operation (which might be 3-to-5 times wider than the occupied bandwidths if linearization techniques are to be used). A detailed description of requirements is given below. 1. Gain For a Power Amplifier, gain is defined as the difference between the power of the RF signal applied to PA input and the one delivered to the antenna port. While this property is the most important for the PA (it is the purpose of Power Amplifiers to create Gain), its actual value is of a lesser importance. Really, the gain of a last stage could be easily increased by adding extra preamplifiers preceding the final stage of a Power Amplifier. That is, the value of the Gain could be reduced for the sake of achieving other parameters (better match, linearity or efficiency). Very often two Gain values are included on PA spec sheets – they are a small signal gain (that is, gain at the significantly reduced level of an input signal; expressed as S21) and a large signal gain (gain at 1 dB compression point). 2. Output Power Power Handling Capability is defined as the maximum power that an amplifier can handle without damage. Its value depends on the size and configuration of a transistor’s die and the proper application of cooling. This parameter should be large enough to sustain an RF power level expected by the Antenna Port. Sometimes it is expressed as “dissipated power” (which is the product of a current flowing through collector/drain and the voltage across the device); however, for high power transistors it is usually given as “output power at 1 dB Compression Point” or “Saturated Power.” 3. Linearity Linearity is the measure of an amplifier’s distortions. Distortions are happening when RF signals with variable envelopes are applied to a nonlinear amplifier; they have to be low enough for the system’s receiver to recognize what the transmitter is sending. Mathematically, the distortions are realized as an interaction between additional spectral components created by the amplifier’s nonlinear transfer function (I-V DC curves). For CW signals their measure is Compression Point or Intercept Point; for digitally modulated signals the figures of merit are Adjacent Channel Power (ACP – the measure of out-of-band interference) and Error Vector Magnitude (EVM – the measure of in-channel distortions). Distortions can be compensated by the application of products with the same amplitude and the opposite polarity to undesirable ones – the process which is called “linearization.” There are two basic approaches to linearization – one of them is called Feedback, where the corrections for creating a distortion-free operation are done at the amplifier’s input (predistorters are operating on this principle), and the other is Feed-Forward, where the corrections are applied to the output of the amplifier. The first approach is cheaper, however it cannot compensate for distortions from heavily compressed amplifiers (above 1 dB compression point). Generic math formulas are given in the appendix. 4. Efficiency Efficiency is a measure of DC energy loss when it is transferred to RF power. In hand-held units, an inefficient PA is draining the battery and producing excessive heat; in high-power stationary units it requires complicated cooling systems and increases the cost of operation. However having ideal sinusoidal RF signal at an amplifier’s output (like in Class A amplifiers) makes the PA lose 50% of its DC power by repeating redundant (positive and negative) information about amplitudes of Voltage and Current; mathematically it is shown by calculating Average Powers, expressed as integrals of instantaneous powers for DC (which is constant) and RF (which is proportional to sin2[t]). In order to increase efficiency, the redundancy of Voltage/Current amplitudes has to be eliminated, which is done with the introduction of a Class B amplifier. In this class a conduction angle is reduced by a biasing amplifier to the origin of its transfer function, which makes the PA transfer only half (positive OR negative) of input RF sinusoids. However, due to the nonlinearities of transfer function (especially pronounced at its origin) – maximum efficiency for this method would not exceed 78%. A better method to increase efficiency is to use a switch modulated by input RF signal. The DC supply of that switch, expressed as Idc*Vdc, is providing a required value for RF output power (when the switch is opened – all DC power is applied to the output load, when it is closed – none is coming to that load; so all DC is applied to the load at intervals directed by input RF data stream). Theoretically this method provides 100% efficiency; the Gain in this model of operation is defined as before (the difference between input and output RF powers); it works because output DC power is higher than input RF one. The obvious issue with this method, however, is that all variations of an input amplitude are lost – so for variable envelopes, one needs to use alternative means of their recovery. Examples of these means are LINC (“Linear amplification with Nonlinear Components” – a method based on idea that any amplitude-modulated signal can be expressed as a sum of two different constant-envelope but phase-modulated signals) and EER (”Envelope Elimination and Restoration” – a method which detects an amplitude of an RF signal, amplifies a phase portion of the RF input signal, and modulates the resulting signal by detected amplitude variation). In order to keep an amplifier’s high efficiency over the range of output powers (vs. achieving it only at the highest level) a technique called Load Modulation is used. For switched amplifiers included in LINC system it is achieved by combining signals from each branch on non-isolated power combiners; however this technique is applied to non-switched amplifiers, too. It is called a Doherty amplifier (the idea of which is to combine very efficient and very linear amplifier on one modulated load), and it allows a reasonable compromise between linearity and efficiency. 5. Stability The RF Power Amplifier has to be stable (that is, oscillation free) over its operational range (over variations in temperature, frequencies, and power levels). Oscillations are caused by a positive feedback from the amplifier’s output; one has to be careful to avoid them or to dump them with additional circuitry. For small signal operations, stable conditions are found from so-called “Stability Factor,” which is a formula derived from S-parameters (parameters describing transfer characteristics of a linear circuit). However, for large signal operations (that is, the most important area of Power Amplifier’s operation) stability has to be determined from Load Pull measurements. Design Flow The typical design of an RF Power Amplifier for a Base Station starts from the requirements supplied by the customer. Based on power and frequency requirements, the output transistors (as a rule – it is a pair of transistors) are to be chosen. Then, based on a budget and requirements, the amplifier’s configuration and class are determined. Input and output matching circuits are designed from load-pull contours, either measured or provided with the transistor’s data sheets. Initial (small signal) simulation of matching circuitry is done based on ideal components and CW input signal. Initial verification of small signal simulations is done on demo boards, provided by the transistors’ manufacturers. Customer requirements should also include a form factor for the amplifier which is a starting point for a mechanical team working on a design of enclosure. From this design an allocated room for a final stage of Power Amplifier is found. Knowing that, a preliminary layout is created and simulated using a large signal simulation with the input waveform supplied by the customer. The first round of simulations is done with still ideal components; at the next round – all known parasitics are to be included. The goal of this simulation is to come up with a PCB layout. When satisfactory results are achieved, EM simulation is conducted in order to include an influence of the enclosure (metal walls and cover) on the layout. The control circuitry team applies their firmware and hardware to the amplifier’s prototype assembled on demo boards. They are to build their final version to the form factor given to them by the mechanical team. Finally, the prototype of the amplifier is assembled into the required enclosure, fine-tuned and then tested using a customer-supplied waveform. In the RF signal chain, the power amplifier (PA) is the active element located between the transmitter signal chain circuitry and the antenna, Figure 1. It is often a single discrete component, one with requirements and parameters which differ from those of much of the transmit chain as well as the receiver circuitry. Many Applications General-purpose RF amplifiers are needed in virtually all wireless designs. Below is just a sample of the broad usage: 4G FDD and TDD base stations 5G base stations Wireless repeaters Distributed antenna systems Infrastructure point-to-point radios Public safety wireless equipment Military radios Test and measurement equipment RF Amplifier Specifications These are the features and specifications to consider in selecting an all-purpose linear RF amplifier. Frequency range: The broader the better for an all-purpose part. Most designs are in the 500-MHz to near 5-GHz range to cover most applications. Gain: This depends on the application, but something in the 10- to 20-dB range is useful. And you want that gain to be the same over a wide frequency range. In most RF amplifiers, the gain will vary somewhat over a wide frequency range. Look for an amplifier with gain flatness over segments over a ±100-MHz range that’s as low as possible, less than about ±0.2 dB. Input/output impedance: 50 Ω, of course. A must standard impedance spec for most RF signal chains. Noise figure: Noise levels are high at these high frequencies. So, noise figure (NF) is usually critical. Remember that NF is a measure of how much noise the amplifier produces. It’s the ratio of the signal-to-noise (S/N or SNR) ratio of the amp input to the signal-to-noise (S/N or SNR) ratio of the amp output expressed in dB. NF = 10log (SNR in/SNR out) A signal chain that adds no noise would have a 0-dB NF. Anything less than about 3 dB is good at these frequencies; the lower the better. Seek out 2 dB as a goal. Output power: This is the maximum power output possible with a 50-Ω load at the highest supply voltage. It’s usually given in dBm, referenced to 1 mW. The typical range is typically 12 to 28 dBm. Third-order intercept and 1-dB compression points: The third-order intercept (IP3) and 1-dB compression (P1dB) points are measures of the linearity and efficiency in an amplifier used for power gain. With most wireless standards using OFDM, CDMA, or some other broadband modulation scheme, good linearity is essential for maximum retention of the data details and best bandwidth usage. As you increase the input power to an amplifier, its output power will rise linearly. At some point the output will begin to flatten or compress, indicating distortion is occurring. Solid-state technology: Amplifiers at these high frequency ranges can be made of CMOS silicon, but more likely they’re made with gallium arsenide (GaAs) or silicon germanium (SiGe). SiGe is generally the more reliable of the two. These compound semiconductors generally perform better than silicon at the higher frequencies. DC power: Most IC RF amplifiers operate from a supply voltage in the 1.8- to 6-V range. Current levels vary with supply voltage and the power generated and can range from 20 mA to over 100 mA. If the amplifier has a standby or low-power mode, current level should drop to no more than a few milliamps. Packaging: Virtually all available amps are surface-mount in tiny packages. DFN and SOT-89 are common, but others are used. Sizes range from 5 × 5 mm down to 2 × 2 mm. Temperature: Most cover the range from −40°C to +85°C or +105°C. _________________________________________________________________________________________________________________________________ RF AMPLIFIER EFFICIENCY BACKGROUND ► The RF Front End (RFFE) is primarily judged by cost, and 4 technical parameters: 1. Output Power 2. Frequency/Bandwidth 3. Linearity 4. Energy Efficiency ► Energy Efficiency is the differentiator ► Usually, the Transmitter/PA consumes the greatest amount of power in the radio, and is the focus for much of the Energy Efficiency development. DEFICIENCY & LOSS : ► All of the circuit components are lossy, dissipating power, reducing energy efficiency. ► Most power losses occur in the device (the controlled current source) itself. ► Simultaneous existence of voltage across, and current through, the device. ► Improvements in energy efficiency are generally made by: 1. Better semiconductor technology 2. Efficiency enhancement schemes FUNDAMENTAL TECHNIQUES ► All techniques for improving efficiency of a device can be broken down and classified: 1. Load Modulation 2. Supply Modulation 3. Waveform Engineering ► Not all enhancement schemes leverage each technique to the same extent. ► Different device technologies exhibit different sensitivities to the techniques. ► Perfectly implemented schemes do not necessarily fully leverage device capabilities. LOAD MODULATION ► In Load Modulation, the load impedance presented to (especially the fundamental frequency) is modified. ► Generally, maximise the voltage swing, the peak-to-peak voltage, across the device. SUPPLY MODULATION ► In Supply Modulation, the supply voltage to the device is modified. ► Generally, the goal is to ensure that the minimum voltage in the RF envelope approaches zero. WAVEFORM ENGINEERING ► In Waveform Engineering, the shapes of the RF waveforms are modified . THEORETICAL LIMIT: MAXIMALLY EFFICIENT ► By applying all 3 techniques optimally, the Maximally Efficient Amplifier can be defined ► Squared-up Voltage and Current waveforms 1. Dissipation in the device is zero, but not necessarily in the other components 2. Anyway, nothing said about how those waveforms are created ► What practical steps can be taken? SUFFICIENTLY EFFICIENT: PRACTICAL LIMIT ► Harmonic Load-Pull measurements, over a range of bias conditions, can explore device performance potential. ► In the worst case, see how much performance is missing with the chosen implementation. ► Alternatively, for example: 1. Identify a complimentary, additional, technique. 2. Identify the most suitable, existing, known, scheme before designing. 3. Implement the device in a novel, highly optimised, scheme. CONCLUSIONS ► Typical off-the-shelf Devices are capable of much better performance than off-the-shelf Enhancement Schemes would have you believe. ► Performing a comprehensive, harmonic Load-pull measurement on a device or technology will, as a minimum, allow you to see just how much performance is missing. ► If efficient RFFE development is your lifeblood, understand which of the 3 fundamental techniques work best for your technology and application. Develop schemes that better leverage them . RF SATCOM design :
The energy efficiency of an RF frontend (RFFE) is a vital characteristic, whether a radio is battery or mains powered. For battery powered, reducing the maximum current drawn from the battery increases the time between charges. For mains powered, important properties such as size, weight and power are dictated by the RFFE efficiency. Consequently, many amplifier architectures and inventions have been developed to minimize wasted energy in the transmitter. Although improving efficiency, some of these rely on theoretically impossible modes of operation, and some fail to fully use the device’s capabilities. fundamental research in RF technology for satellite communication. RF SATELLITE COMMUNICATION? Ecosyatem design : Within this ecosystem we like to act as your preferred partner for applied research and technology developments to enable future design . the focus design is on phased array antenna systems and the building blocks they encompass. Whether you need a break-through step in MMIC design using GaN technology, multipaction-free analogue front-end design, wide steering phased antenna design or RF lens antennas, you can rely on TNO to translate state-of-the art research results into new SatCom technology. MMIC DESIGN AND TESTING the design and testing of Monolithic Microwave Integrated Circuits (MMICs) in GaAs, GaN and SiGe technology. MMICs designs have been successful, ranging from L-band to W-band, with the focus on components for phased array radar front-ends and telecommunication. Examples of such components are high-power amplifiers, multi-function chips (beamformers), mixers, and low-noise amplifiers. FRONT-END ELECTRONICS / BEAM FORMING NETWORK For RF and µWave communication systems, Front-End electronics is planning design to ranging from the synthesised RF/µWave signal generation, specific modulation (data/frequency) and power amplification for the transmit signal to low noise amplification, demodulation and high-speed sampling/digitization of the receive signal. TNO has a strong and long heritage in designing such Front-End electronics for all kinds of Radar and Communication systems, optimised for the specific requirements of the application, either for steerable ‘single-beam’ as well as for ‘multi-beam’ array systems. ____________________________________________________________________________________________________________________________ RF for the future of life as the basis for the language of telecommunications Electronics base station keeping teritory
SMART ELECTRONICS WITH TIME WINDOWS
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Kamis, 10 Desember 2020

" STATION KEEPING " Advances in satellite technology " SATCOM " AMNIMARJESLOW GOVERNMENT 17th to be relaxed, polite, pure, one hundred percent ; Repositioning , Refreshing , Reborn and Revalue added ****

When the world becomes easier, transparent and more dynamic as it is today, the ability to communicate between humans and other forms of life can be done and that is something possible with advances in pure electronics and sensors, the progress we are getting today is the development of satellites. Communication known as SATCOM, SATCOM is a combination of performance capabilities in the field of electronic theory and materials and control instrumentation, namely the development of oscilloscopes, power supply and network analyzers as well as electronic learning machines or so-called artificial intelligence. SATCOM in the future can be used for long-distance navigation for spacecraft that are several light years speed and penetrate dimensional space outside our solar system. In the future, the development of satellites can become a wave guide for space shuttle travel and move around the aircraft following the motion of the space ship. Let's look at the basic concept of network analysis using electronic sensor sensors on the Surface mount technology machine, which already uses a very meticulous integrated communication system.
*** SAT COM *** _________________ All space vehicles will require some source of electrical power for operation of communication equipment, instrumentation, environment controls, and so forth. In addition, vehicles using electrical propulsion systems like ion rockets will have very heavy power requirements. Current satellites and space probes have relatively low electrical power requirements-of the order of a few watts. Bolder and more sophisticated space missions will lead to larger power needs. For example, a live television broadcast from the Moon, may require kilowatts of power.1 Over the distance from Earth to Mars at close approach, even a low-capacity instrumentation link might easily require hundreds of kilowatts of power.2 The net power needs of men in space vehicles are less clearly defined, but can probably be characterized as "large."3 Electrical propulsion systems will consume power at the rate of millions of watts per pound of thrust. Power supply requirements cannot be based on average power demands alone. A very important consideration is the peak demand. For example, a radio ranging device may have an average power of only 2 watts, but it may also require a 600-watt peak. Unfortunately most foreseeable systems are severely limited in their ability to supply high drain rates; consequently they must be designed with a continuous capacity nearly equal to the peak demand. A third important consideration is the voltage required. Voltage demand may be low for motors or high for various electronic applications. Furthermore, alternating current may be required or may be interchangeable with direct current. Transformations of voltage and/or direct to alternating current may be effected, but with a weight penalty . BATTERIES ___________ The power supply most readily available is the battery, which converts chemical to electrical energy. The theoretical performance figures refer to cells in which all of the cell material enters completely into the electrochemical reaction.These theoretical limits, are, of course, unobtainable in practice because of the necessity for separators, containers, connectors etc. The hydrogen-oxygen (H2-O2) system refers to a fuel cell. ASTRONAUTICS AND ITS APPLICATIONS ___________________________________ Hydrogen and oxygen, stored under pressure, take the p]ace of standard electrodes in a battery reaction, and about 60 percent of the heat of combustion is available as electrical energy.6 The figures listed under "Currently available performance" in table 1 refer to long discharge rates (in excess of 24 hours) and normal temperatures. Batteries as prime energy sources do not give really long lifetimes; they do not operate well at low ambient temperatures or under heavy loads. Batteries are best suited to be storage devices to supply peak loads to supplement some other prime source of energy. Other factors to be considered with regard to chemical batteries are: (1) They are essentially low-voltage devices, a battery pack being limited to about 10 kilovolts by reliability limitations; (2) a high-vacuum environment and some forms of solar radiation may have deleterious effects; and (3) many batteries form gas during charge and have to be vented, which is in conflict with the need for hermetic sealing to eliminate loss of electrolyte in the vacuum environment of space. SOLAR POWER ___________ Solar energy arrives in the neighborhood of the Earth at the rate of about 1.35 kilowatts per square meter. This energy can be tapped by direct conversion into electricity through the use of solar cells (solar batteries), or collected 7 to heat a working fluid which can then be used to run some sort of engine to deliver electrical energy. Solar cells are constructed of specially treated silicon wafers, and are very expensive to manufacture. They cost about $100 per watt of power capacity. ASTRONAUTICS AND ITS APPLICATIONS _________________________________ been estimated that solar cells should survive for many years in a solar environment.Surface cooling may be necessary for use of solar cells. For satellite applications of solar cells there is a need to store energy for use during periods of darkness. This storage is the sort of application for which batteries are appropriate. As a rough indication of total weight, a combined installation of solar cells and storage batteries can be expected to weigh about 700 pounds per kilowatt of capacity. There are a number of possible future improvements in solar cells. Of all the energy striking a solar cell, part is effectively used in producing electrical energy, part is reflected (about 50 percent), and part is actually transmitted through the cell, particularly in the lower wavelength end of the spectrum. Therefore one improvement would be to reduce the reflectivity of the cell; another would be to make the cells thinner. Another possibility might be to actually concentrate solar energy through a lightweight plastic lens. It would be desirable to develop cells for high-temperature operation. Temperature control problems for solar cells have been investigated in the U.S.S.R. for satellite applications. The second possibility for utilizing solar energy is through heating of a working fluid. a standard for a half-silvered inflated mylar plastic sphere (about 1 Mil thick) 8.5 feet in radius, might serve as a collector,13 at a weight cost of only about 8 pounds per 30 kilowatts of collected thermal energy.14 An installation of this size would require roughly 100 square feet of radiator to reject waste heat (assuming a 10-percent overall conversion efficiency). This kind of system is roughly similar to a solar cell system as to weight for a given power capacity. Again meteorite effects present an unknown factor, in this case with respect to puncture of the collecting sphere and/or the radiator. The greater the actual meteorite hazard turns out to be, the thicker and consequently the heavier the radiator will have to become. The development potential of solar energy sources seems good.
**** Network and Protocol **** _______________________________ A network protocol analyzer is a tool used to monitor data traffic and analyze captured signals as they travel across communication channels. Vector Network Analyzers are used to test component specifications and verify design simulations to make sure systems and their components work properly together. Today, the term “network analyzer”, is used to describe tools for a variety of “networks”. For network performance measurement, throughput is defined in terms of the amount of data or number of data packets that can be delivered in a pre-defined time frame. Bandwidth, usually measured in bits per second, is a characterization of the amount of data that can be transferred over a given time period. Electronic distribution of information is becoming increasingly important, and the complexity of the data exchanged between systems is increasing at a rapid pace. Computer networks today carry all kinds of data, voice, and video traffic. Network applications require full availability without interruption or congestion. As the information systems in a company grow and develop, more networking devices are deployed, resulting in large physical ranges covered by the networked system. It is crucial that this networked system operates as effectively as possible, because downtime is both costly and an inefficient use of available resources. Network and/or protocol analysis is a range of techniques that network engineers and technicians use to study the properties of networks, including connectivity, capacity, and performance. Network analysis can be used to estimate the capacity of an existing network, look at performance characteristics, or plan for future applications and upgrades. A network analyzer is a device that gives you a very good idea of what is happening on a network by allowing you to look at the actual data that travels over it, packet by packet. A typical network analyzer understands many protocols, which enables it to display conversations taking place between hosts on a network. Network analyzers typically provide the following capabilities: •Capture and decode data on a network •Analyze network activity involving specific protocols •Generate and display statistics about the network activity •Perform pattern analysis of the network activity. Packet capture and protocol decoding is sometimes referred to as “sniffing.” This term came about because of the nature of the network analyzers ability to “sniff” traffic on the network and capture it. Electronic distribution of information is becoming increasingly important, and the complexity of the data exchanged between systems is increasing at a rapid pace. Computer networks today carry all kinds of data, voice, and video traffic. Network applications require full availability without interruption or congestion. As the information systems in a company grow and develop, more networking devices are deployed, resulting in large physical ranges covered by the networked system. It is crucial that this networked system operate as effectively as possible, because downtime is both costly and an inefficient use of available resources. Network analysis is a range of techniques that network engineers and designers employ to study the properties of networks, including connectivity, capacity, and performance. Network analysis can be used to estimate the capacity of an existing network, look at performance characteristics, or plan for future applications and upgrades. A network analyzer is a troubleshooting tool that is used to find and solve network communication problems, plan network capacity, and perform network optimization. Network analyzers can capture all the traffic that is going across your network and interpret the captured traffic to decode and interpret the different protocols in use. The decoded data is shown in a format that makes it easy to understand. A network analyzer can also capture only traffic that matches only the selection criteria as defined by a filter. This allows a technician to capture only traffic that is relevant to the problem at hand. A typical network analyzer displays the decoded data in three panes: ▪Summary Displays a one-line summary of the highest-layer protocol contained in the frame, as well as the time of the capture and the source and destination addresses. ▪Detail Provides details on all the layers inside the frame.Hex Displays the raw captured data in hexadecimal format. A network professional can easily use this type of interface to analyze this data. Network analyzers further provide the ability to create display filters so that a network professional can quickly find what he or she is looking for. Advanced network analyzers provide pattern analysis capabilities. This feature allows the network analyzer to go through thousands of packets and identify problems. The network analyzer can also provide possible causes for these problems and hints on how to resolve them. The key to successful troubleshooting is knowing how the network functions under normal conditions. This knowledge allows a network professional to quickly recognize abnormal operations. Using a strategy for network troubleshooting, the problem can be approached methodically and resolved with minimum disruption to customers. Unfortunately, sometimes even network professionals with years of experience have not mastered the basic concept of troubleshooting; a few minutes spent evaluating the symptoms can save hours of time lost chasing the wrong problem. A good approach to problem resolution involves these steps: 1.Recognizing symptoms and defining the problem 2.Isolating and understanding the problem 3.Identifying and testing the cause of the problem 4.Solving the problem 5.Verifying that the problem has been resolved A very important part of troubleshooting is performing research. The Internet can be a valuable source of information on a variety of network topics and can provide access to tutorials, discussion forums, and reference materials. As a part of your troubleshooting methodology, you can use the Internet as a tool to perform searches on errors or symptoms that you see on your network. The first step toward trying to solve a network issue is to recognize the symptoms. You might hear about a problem in one of many ways: an end user might complain that he or she is experiencing performance or connectivity issues, or a network management station might notify you about it. Compare the problem to normal operation. Determine whether something was changed on the network just before the problem started. In addition, check to make sure you are not troubleshooting something that has never worked before. Write down a clear definition of the problem. Once the problem has been confirmed and the symptoms identified, the next step is to isolate and understand the problem. When the symptoms occur, it is your responsibility to gather data for analysis and to narrow down the location of the problem. The best approach to reducing the problem's scope is to use divide-and-conquer methods. Try to figure out if the problem is related to a segment of the network or a single station. Determine if the problem can be duplicated elsewhere on the network. The third step in problem resolution is to identify and test the cause of the problem and test your hypothesis. You can use network analyzers and other tools to analyze the traffic. After you develop a theory about the cause of the problem, you must test it. Once a resolution to the problem has been determined, it should be put in place. The solution might involve upgrading hardware or software. It may call for increasing LAN segmentation or upgrading hardware to increase capacity. The final step is to ensure that the entire problem has been resolved by having the end customer test for the problem. Sometimes a fix for one problem creates a new problem. At other times, the problem you repaired turns out to be a symptom of a deeper underlying problem. If the problem is indeed resolved, you should document the steps you took to resolve it. If, however, the problem still exists, the problem-solving process must be repeated from the beginning. When a network analyzer reads data from the network it needs to know how to interpret what it is seeing and display the output in an easy to read format. This is known as protocol decoding. Often, the number of protocols a sniffer can read and display determines its strength, thus most commercial sniffers can support several hundred protocols. Ethereal is very competitive in this area with its current support of over 480 protocols. New protocols are constantly being added by various contributors to the Ethereal project. Protocol decodes, also known as dissectors, can be added directly into the code or included as plugins. How is network quality measured? Some common metrics used to measure network performance include latency, packet loss indicators, jitter, bandwidth, and throughput. ------------------------------------------------------------------------------------------------------------------------------ ***** Oscilosscope ***** __________________________ Oscilloscopes are used in the sciences, medicine, engineering, automotive and the telecommunications industry. General-purpose instruments are used for maintenance of electronic equipment and laboratory work. Special-purpose oscilloscopes may be used to analyze an automotive ignition system or to display the waveform of the heartbeat as an electrocardiogram, for instance. An oscilloscope, previously called an oscillograph , and informally known as a scope or o-scope, CRO (for cathode-ray oscilloscope), or DSO (for the more modern digital storage oscilloscope), is a type of electronic test instrument that graphically displays varying signal voltages, usually as a calibrated two-dimensional plot of one or more signals as a function of time. The displayed waveform can then be analyzed for properties such as amplitude, frequency, rise time, time interval, distortion, and others. Originally, calculation of these values required manually measuring the waveform against the scales built into the screen of the instrument. Modern digital instruments may calculate and display these properties directly. The oscilloscope can be adjusted so that repetitive signals can be observed as a persistent waveform on the screen. A storage oscilloscope can capture a single event and display it continuously, so the user can observe events that would otherwise appear too briefly to see directly. Most modern oscilloscopes are lightweight, portable instruments compact enough for a single person to carry. In addition to portable units, the market offers a number of miniature battery-powered instruments for field service applications. Laboratory grade oscilloscopes, especially older units that use vacuum tubes, are generally bench-top devices or are mounted on dedicated carts. Special-purpose oscilloscopes may be rack-mounted or permanently mounted into a custom instrument housing. Automotive use First appearing in the 1970s for ignition system analysis, automotive oscilloscopes are becoming an important workshop tool for testing sensors and output signals on electronic engine management systems, braking and stability systems. Some oscilloscopes can trigger and decode serial bus messages, such as the CAN bus commonly used in automotive applications.
--------------------------------------------------------------------------------------------------------------------------------- ****** SATCOM ADVANCE FOR STATION KEEPING ****** ___________________________________________________ Advances in satellite technology have given rise to a healthy satellite services sector that provides various services to broadcasters, Internet service providers (ISPs), governments, the military, and other sectors. There are three types of communication services that satellites provide: telecommunications, broadcasting, and data communications. Telecommunication services include telephone calls and services provided to telephone companies, as well as wireless, mobile, and cellular network providers. Broadcasting services include radio and television delivered directly to the consumer and mobile broadcasting services. DTH, or satellite television, services (such as the DirecTV and DISH Network services in the United States) are received directly by households. Cable and network programming is delivered to local stations and affiliates largely via satellite. Satellites also play an important role in delivering programming to cell phones and other mobile devices, such as personal digital assistants and laptops. Satellite communications use the very high-frequency range of 1–50 gigahertz (GHz; 1 gigahertz = 1,000,000,000 hertz) to transmit and receive signals. The frequency ranges or bands are identified by letters: (in order from low to high frequency) L-, S-, C-, X-, Ku-, Ka-, and V-bands. Signals in the lower range (L-, S-, and C-bands) of the satellite frequency spectrum are transmitted with low power, and thus larger antennas are needed to receive these signals. Signals in the higher end (X-, Ku-, Ka-, and V-bands) of this spectrum have more power; therefore, dishes as small as 45 cm (18 inches) in diameter can receive them. This makes the Ku-band and Ka-band spectrum ideal for direct-to-home (DTH) broadcasting, broadband data communications, and mobile telephony and data applications. The International Telecommunication Union (ITU), a specialized agency of the United Nations, regulates satellite communications. The ITU, which is based in Geneva, Switzerland, receives and approves applications for use of orbital slots for satellites. Every two to four years the ITU convenes the World Radiocommunication Conference, which is responsible for assigning frequencies to various applications in various regions of the world. Each country’s telecommunications regulatory agency enforces these regulations and awards licenses to users of various frequencies. In the United States the regulatory body that governs frequency allocation and licensing is the Federal Communications Commission. Satellites operate in three different orbits: low Earth orbit (LEO), medium Earth orbit (MEO), and geostationary or geosynchronous orbit (GEO). LEO satellites are positioned at an altitude between 160 km and 1,600 km (100 and 1,000 miles) above Earth. MEO satellites operate from 10,000 to 20,000 km (6,300 to 12,500 miles) from Earth. (Satellites do not operate between LEO and MEO because of the inhospitable environment for electronic components in that area, which is caused by the Van Allen radiation belt.) GEO satellites are positioned 35,786 km (22,236 miles) above Earth, where they complete one orbit in 24 hours and thus remain fixed over one spot. As mentioned above, it only takes three GEO satellites to provide global coverage, while it takes 20 or more satellites to cover the entire Earth from LEO and 10 or more in MEO. In addition, communicating with satellites in LEO and MEO requires tracking antennas on the ground to ensure seamless connection between satellites. A signal that is bounced off a GEO satellite takes approximately 0.22 second to travel at the speed of light from Earth to the satellite and back. This delay poses some problems for applications such as voice services and mobile telephony. Therefore, most mobile and voice services usually use LEO or MEO satellites to avoid the signal delays resulting from the inherent latency in GEO satellites. GEO satellites are usually used for broadcasting and data applications because of the larger area on the ground that they can cover. Satellites operate in extreme temperatures from −150 °C (−238 °F) to 150 °C (300 °F) and may be subject to radiation in space. Satellite components that can be exposed to radiation are shielded with aluminium and other radiation-resistant material. A satellite’s thermal system protects its sensitive electronic and mechanical components and maintains it in its optimum functioning temperature to ensure its continuous operation. A satellite’s thermal system also protects sensitive satellite components from the extreme changes in temperature by activation of cooling mechanisms when it gets too hot or heating systems when it gets too cold. The tracking telemetry and control (TT&C) system of a satellite is a two-way communication link between the satellite and TT&C on the ground. This allows a ground station to track a satellite’s position and control the satellite’s propulsion, thermal, and other systems. It can also monitor the temperature, electrical voltages, and other important parameters of a satellite. The main components of a satellite consist of the communications system, which includes the antennas and transponders that receive and retransmit signals, the power system, which includes the solar panels that provide power, and the propulsion system, which includes the rockets that propel the satellite. A satellite needs its own propulsion system to get itself to the right orbital location and to make occasional corrections to that position. A satellite in geostationary orbit can deviate up to a degree every year from north to south or east to west of its location because of the gravitational pull of the Moon and Sun. A satellite has thrusters that are fired occasionally to make adjustments in its position. The maintenance of a satellite’s orbital position is called “station keeping,” and the corrections made by using the satellite’s thrusters are called “attitude control.” A satellite’s life span is determined by the amount of fuel it has to power these thrusters. Once the fuel runs out, the satellite eventually drifts into space and out of operation, becoming space debris. A satellite in orbit has to operate continuously over its entire life span. It needs internal power to be able to operate its electronic systems and communications payload. The main source of power is sunlight, which is harnessed by the satellite’s solar panels. A satellite also has batteries on board to provide power when the Sun is blocked by Earth. The batteries are recharged by the excess current generated by the solar panels when there is sunlight. Data communications involve the transfer of data from one point to another. Corporations and organizations that require financial and other information to be exchanged between their various locations use satellites to facilitate the transfer of data through the use of very small-aperture terminal (VSAT) networks. With the growth of the Internet, a significant amount of Internet traffic goes through satellites, making ISPs one of the largest customers for satellite services. Satellite communications technology is often used during natural disasters and emergencies when land-based communication services are down. Mobile satellite equipment can be deployed to disaster areas to provide emergency communication services. One major technical disadvantage of satellites, particularly those in geostationary orbit, is an inherent delay in transmission. While there are ways to compensate for this delay, it makes some applications that require real-time transmission and feedback, such as voice communications, not ideal for satellites. Satellites face competition from other media such as fibre optics, cable, and other land-based delivery systems such as microwaves and even power lines. The main advantage of satellites is that they can distribute signals from one point to many locations. As such, satellite technology is ideal for “point-to-multipoint” communications such as broadcasting. Satellite communication does not require massive investments on the ground—making it ideal for underserved and isolated areas with dispersed populations. Satellites and other delivery mechanisms such as fibre optics, cable, and other terrestrial networks are not mutually exclusive. A combination of various delivery mechanisms may be needed, which has given rise to various hybrid solutions where satellites can be one of the links in the chain in combination with other media. Ground service providers called “teleports” have the capability to receive and transmit signals from satellites and also provide connectivity with other terrestrial networks. The future of satellite communication In a relatively short span of time, satellite technology has developed from the experimental (Sputnik in 1957) to the sophisticated and powerful. Mega-constellations of thousands of satellites designed to bring Internet access to anywhere on Earth are in development. Future communication satellites will have more onboard processing capabilities, more power, and larger-aperture antennas that will enable satellites to handle more bandwidth. Further improvements in satellites’ propulsion and power systems will increase their service life to 20–30 years from the current 10–15 years. In addition, other technical innovations such as low-cost reusable launch vehicles are in development. With increasing video, voice, and data traffic requiring larger amounts of bandwidth, there is no dearth of emerging applications that will drive demand for the satellite services in the years to come. The demand for more bandwidth, coupled with the continuing innovation and development of satellite technology, will ensure the long-term viability of the commercial satellite industry well into the 21st century. ****** TO BE STATION KEEPING ******* Station keeping may refer to: Orbital station-keeping, manoeuvres used to keep a spacecraft in an assigned orbit. Nautical stationkeeping, maintaining a seagoing vessel in a position relative to other vessels or a fixed point. The orbit control process required to maintain a stationary orbit is called station-keeping. Station-keeping is necessary to offset the effect of perturbations, principally due to the Earth's triaxiality and lunar and solar attractions, which tend to precess the orbit normal and alter the orbital energy. Current station keeping equipment (SKE) relies on radio waves for formation flying. A significant limitation of conventional SKE signals is that they are detectable at long distances by adversaries. In astrodynamics, orbital station-keeping are the orbital maneuvers made by thruster burns that are needed to keep a spacecraft in a particular assigned orbit. For many Earth satellites, the effects of the non-Keplerian forces, i.e. the deviations of the gravitational force of the Earth from that of a homogeneous sphere, gravitational forces from Sun/Moon, solar radiation pressure and air drag, must be counteracted. The deviation of Earth's gravity field from that of a homogeneous sphere and gravitational forces from the Sun and Moon will in general perturb the orbital plane. For a sun-synchronous orbit, the precession of the orbital plane caused by the oblateness of the Earth is a desirable feature that is part of mission design but the inclination change caused by the gravitational forces of the Sun and Moon is undesirable. For geostationary spacecraft, the inclination change caused by the gravitational forces of the Sun and Moon must be counteracted by a rather large expense of fuel, as the inclination should be kept sufficiently small for the spacecraft to be tracked by non-steerable antennae. For spacecraft in a low orbit, the effects of atmospheric drag must often be compensated for, oftentimes to avoid re-entry; for missions requiring the orbit to be accurately synchronized with the earth’s rotation, this is necessary to prevent a shortening of the orbital period. Solar radiation pressure will in general perturb the eccentricity (i.e. the eccentricity vector); see Orbital perturbation analysis (spacecraft). For some missions, this must be actively counter-acted with manoeuvres. For geostationary spacecraft, the eccentricity must be kept sufficiently small for a spacecraft to be tracked with a non-steerable antenna. Also for Earth observation spacecraft for which a very repetitive orbit with a fixed ground track is desirable, the eccentricity vector should be kept as fixed as possible. A large part of this compensation can be done by using a frozen orbit design, but oftentimes thrusters are needed for fine control manoeuvres. For spacecraft in a halo orbit around a Lagrange point, station-keeping is even more fundamental, as such an orbit is unstable; without an active control with thruster burns, the smallest deviation in position or velocity would result in the spacecraft leaving orbit completely . Station-keeping at libration points Orbits of spacecraft are also possible around Lagrange points—also referred to as libration points—gravity wells that exist at five points in relation to two larger solar system bodies. For example, there are five of these points in the Sun-Earth system, five in the Earth-Moon system, and so on. Small spacecraft may orbit around these gravity wells with a minimum of propellant required for station-keeping purposes. Two orbits that have been used for such purposes include halo and Lissajous orbits. Orbits around libration points are dynamically unstable, meaning small departures from equilibrium grow exponentially over time. As a result, spacecraft in libration point orbits must use propulsion systems to perform orbital station-keeping. The attitude & orbit control system (AOCS) controls the attitude and position of a complete space vehicle or satellite. Based on this function, the spacecraft orients its solar generators, thermal radiators, thrusters and particularly its payload units, optical instruments and antennas. --------------------------------------------------------------------------------------------------------------------------------- *********** We Look FUTURE TECHNOLOGY by ME *************
++ SATELLITE COMMUNICATION TO BE STATION KEEPING FOR ALL ELECTRONICS SENSE CONTROLLING Machine Learning ++ ________________________________________________________________________________________________________________________________