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Atmospheric noise

Atmospheric noise, also known as sferics or atmospherics, refers to the impulsive, electromagnetic radiation in the radio-frequency spectrum generated primarily by discharges within the Earth's atmosphere. This natural phenomenon produces random electrical disturbances that interfere with radio signal reception, particularly in the low-frequency (LF), medium-frequency (), and high-frequency () bands, where it manifests as static or crackling sounds in receivers. The primary source of atmospheric noise is the electrical discharges from lightning strokes in thunderstorms, which radiate energy across a wide range of frequencies, typically from 10 kHz to 30 MHz, with peak effects below 10 MHz. These discharges generate short-duration pulses, or atmospherics, that propagate globally via reflection between the Earth's surface and the , leading to variations in noise intensity based on geographic location, season, and time of day. For instance, noise levels are generally higher in tropical regions during local summer afternoons due to increased thunderstorm activity, and they exhibit diurnal patterns with maxima around 0000-0400 in winter hemispheres. Worldwide measurements indicate median levels can range from 20 to 100 above thermal noise (kT_b), with standard deviations of 5-15 reflecting temporal and spatial variability. Atmospheric noise is characterized by its non-Gaussian, impulsive nature, often described using amplitude probability distributions (APDs) that capture voltage exceedance probabilities, with a key parameter being the voltage deviation (V_d), typically around 20 for a 0.5% exceedance probability. Unlike thermal noise, it is not stationary and includes both intra-cloud and cloud-to-ground lightning contributions, though the latter produces stronger signals. Its effects on telecommunication systems are profound, elevating the overall and degrading signal-to-noise ratios (SNR), which limits the performance of analog and links, especially in long-range HF propagation. Accurate modeling, such as that provided by international standards, is essential for system design to mitigate these impacts through techniques like frequency selection or error correction.

Definition and Fundamentals

Definition

Atmospheric noise, also known as radio atmospheric noise or static, refers to the electromagnetic interference in the spectrum generated by natural electrical processes within Earth's atmosphere, primarily from discharges in thunderstorms. These discharges produce impulsive radio signals called sferics, which manifest as crackling or popping sounds in radio receivers and can span frequencies from (VLF) to (HF) bands. Globally, lightning occurs at an average rate of approximately 47 flashes per second, equivalent to about 4 million flashes per day, ensuring a continuous background of atmospheric noise that varies diurnally and seasonally due to activity. This noise is distinct from man-made , which arises from industrial and electronic sources such as power lines and appliances, and from cosmic noise originating from extraterrestrial sources like stars and galaxies; atmospheric noise is strictly terrestrial and tied to phenomena. Key manifestations of atmospheric noise include sferics as the primary impulses and tweeks as ionospherically dispersed sferics that produce a characteristic whistling or tweeting audio effect in VLF receivers.

Physical Characteristics

Atmospheric noise is characterized by a frequency that peaks prominently in the (VLF: 3–30 kHz) and (LF: 30–300 kHz) bands, where it dominates over other noise sources. This includes both impulsive components from discrete events and quasi-white elements, resulting in a power that decreases by approximately 30 dB from 10 kHz to 80 kHz, with a steeper drop in the 10–20 kHz range. Above these bands, the noise level diminishes, but it remains significant up to several megahertz, influencing radio systems in those ranges. The amplitude of atmospheric noise exhibits substantial variability across different timescales and locations. Diurnally, levels peak during midday hours (around 1200–1600 local time) due to enhanced generation mechanisms, with daily fluctuations of 3–15 dB. Seasonally, noise is highest in summer months like June–July–August, showing monthly variations up to 23 dB in active regions, while yearly changes are milder at less than 1.5 dB. Geographically, intensity is elevated in tropical areas such as parts of Africa and South America, where noise figures can reach 60–70 dB at 1 MHz during peak periods, compared to lower values in polar or arid zones. Waveforms of atmospheric noise typically appear as short, impulsive bursts from individual events, lasting microseconds to milliseconds with high peak amplitudes, contrasted by a continuous hiss-like background formed by the overlapping signals from numerous distant sources. This impulsiveness is evident in bands, where the voltage deviation (V_d) typically ranges from 15 to 25 , indicating strong non-Gaussian statistics, though overlapping impulses in stormy areas can produce more continuous spectra. Quantification of atmospheric noise commonly employs the noise figure (F_a), measured in decibels above the standard thermal noise level (kT_0 B, where T_0 = 290 K), providing a standardized for its excess strength. In VLF and LF bands, F_a values typically range from about 50 at 10 kHz to 30–40 at 1 MHz for median conditions, with extremes exceeding 60 during high-activity periods, as outlined in ITU recommendations. This measure facilitates comparisons across frequencies and environments without delving into absolute power levels.

Sources of Atmospheric Noise

Lightning Discharges

Lightning discharges are the primary source of atmospheric noise, generating broadband electromagnetic primarily through the rapid acceleration of electrons during return strokes in both cloud-to-ground () and intracloud () lightning flashes. In a return stroke, the sudden neutralization of charge separation along the channel produces intense current pulses that radiate energy across a wide , with the through the abrupt changes in along the channel, producing similar to that from a vertical . These pulses, known as sferics, originate from the abrupt changes in , typically on the order of tens of kiloamperes, propagating as impulsive signals detectable over long distances. Cloud-to-ground lightning contributes stronger, more intense impulses due to the direct connection to the Earth's surface, which enhances the vertical radiation pattern and results in higher peak field strengths. In contrast, intracloud lightning, which occurs between charge regions within a single , produces more frequent but generally weaker emissions, often manifesting as smaller negative slow-tail sferics. Globally, lightning activity—and thus atmospheric noise generation—is concentrated in equatorial regions, particularly over tropical landmasses like the and , where convective thunderstorms are most prevalent, accounting for a land-to-ocean ratio of approximately 10:1 in flash density. The radio pulses from these discharges exhibit characteristic durations on the order of microseconds for the initial , though the full can extend to tens of microseconds depending on the stroke's . Their bandwidth typically spans up to 100 kHz in the (VLF) to (LF) bands, with spectral peaks often around 5-20 kHz, enabling propagation via the Earth-ionosphere . Each return stroke releases up to 10^9 joules, a portion of which—on average around 10^4 joules in radiated VLF energy—manifests as these radio emissions. Lightning accounts for essentially all atmospheric noise in the VLF/LF bands, dominating over 90% of the in relevant radio frequencies, as evidenced by the impulsive "crackles" and static bursts commonly heard on (AM) radios during thunderstorms. These pulses propagate globally, with their detection influenced by modes that allow circumplanetary travel.

Other Atmospheric Phenomena

Precipitation static, often abbreviated as p-static, arises from the interaction of charged particles in precipitation such as rain, snow, or dust storms with antennas or aircraft surfaces, leading to corona discharges that generate broadband radio noise primarily in the VLF and LF bands. This noise manifests as continuous or semi-continuous interference, distinct from the impulsive signals of lightning, and is particularly problematic for aviation receivers due to charge buildup on non-conductive structures like radomes. Schumann resonances represent low-frequency electromagnetic waves trapped in the Earth-ionosphere cavity, with the fundamental mode at approximately 7.8 Hz and higher harmonics at 14.3 Hz, 20.8 Hz, and beyond, excited primarily by global lightning activity but producing a persistent background noise spectrum in the ELF band. These resonances exhibit diurnal and seasonal variations influenced by ionospheric conditions, offering a global signature of atmospheric electrical activity that overlaps with but is separable from discrete lightning events through their quasi-continuous waveform. Solar flares and auroral phenomena contribute to atmospheric noise via ionospheric disturbances that enhance VLF emissions, with solar bursts increasing D-region and causing signal perturbations up to tens of decibels, while auroral of charged particles generates VLF hiss and emissions in polar regions. These effects produce narrower-band noise compared to the broadband nature of lightning-generated atmospherics, often manifesting during geomagnetic storms or high solar activity periods. Collectively, these secondary sources—precipitation static, , and solar/auroral effects—account for less than 10% of overall atmospheric radio noise power, particularly below 30 MHz, where dominates; their signatures are identifiable by characteristics such as versus impulsiveness and specific peaks, though overlap with primary sources complicates isolation.

Propagation and Detection

Propagation Mechanisms

Atmospheric noise, primarily generated by discharges, propagates through distinct modes depending on frequency and environmental conditions. At lower frequencies such as (LF, 30–300 kHz) and (MF, 300 kHz–3 MHz), propagation dominates, where electromagnetic waves follow the curvature of the Earth's surface, hugging the ground and experiencing gradual attenuation due to soil conductivity and terrain irregularities. This mode enables reliable reception over hundreds of kilometers, particularly over conductive seawater paths, making it significant for regional atmospheric noise contributions in these bands. In contrast, (VLF, 3–30 kHz) components, which carry the bulk of atmospheric noise energy, primarily utilize skywave propagation via the Earth-ionosphere waveguide, involving multiple reflections between the conductive ground and the ionospheric D-layer at approximately 70–90 km altitude. This waveguide mode, first theoretically described by James Wait, supports efficient long-distance travel with minimal loss per hop, as the waves are trapped and guided around the globe. Attenuation of these propagating signals varies diurnally due to ionospheric dynamics. During , the D-layer of the , formed by , absorbs VLF waves significantly, with rates of about 2–5 per 1000 for the dominant over good paths, thereby reducing levels from distant sources and limiting effective propagation to shorter ranges. At night, the D-layer dissipates due to recombination of ions in the absence of , lowering to near negligible levels (often 0.5–1 per 1000 ), which enhances propagation and increases receivable atmospheric from remote thunderstorms. This diurnal variation is particularly pronounced in the , where daytime conditions favor higher-order with greater loss, while nighttime supports dominant low-order for clearer, stronger signals. Dispersion arises from the frequency-dependent in the Earth-ionosphere , causing higher to travel faster than lower ones during . This effect is evident in VLF sferics, which disperse into "tweeks"—characteristic whistling signals where the stretches, with lower arriving later, producing rising tones in spectrograms. Tweeks typically result from single-hop paths of 5,000–15,000 km, with rates of about 10–20 ms per , allowing estimation of distances from the time delay between components. The global reach of atmospheric noise is facilitated by multiple hops in the , enabling reception of lightning-generated signals from thousands of kilometers away, including transoceanic paths. For instance, VLF sferics from thunderstorms can be detected in after 3–5 hops around the , with total distances exceeding 20,000 km and as low as 0.1–0.5 per Mm at night. This multi-hop mechanism underpins global lightning monitoring networks, where noise from equatorial storm clusters dominates mid-latitude receivers due to efficient waveguide guidance.

Detection Methods

Detection of atmospheric noise primarily relies on specialized receivers designed to capture (VLF) and (LF) signals in the 10-100 kHz range, where such noise is most prominent. Broadband antennas, such as loop antennas for detection or vertical whip antennas for sensing, are commonly coupled with spectrum analyzers or dedicated VLF/LF receivers to observe these impulsive signals. Loop antennas, often multi-turn and crossed for directional sensitivity, provide effective area coverage up to several hundred square meters, while vertical whips offer simplicity for portable measurements. These systems enable the of atmospheric noise from local , leveraging the characteristics that allow distant lightning-generated signals to be detectable over thousands of kilometers. Recording approaches for atmospheric noise emphasize capturing its impulsive nature through time-domain methods, such as oscilloscopes that record voltage waveforms of individual sferics or noise bursts. These instruments provide direct of pulse amplitudes and durations, essential for analyzing the transient components of noise events. For frequency-domain characterization, (FFT)-based spectrum analysis is employed to compute , revealing the distribution of energy across VLF/LF bands. This dual approach allows researchers to quantify both temporal profiles and content, with FFT processing typically applied to digitized time-series data from receivers. Field setups utilize portable noise monitors equipped with compact VLF and integrated data loggers for on-site surveys, enabling real-time assessment of local atmospheric noise levels during propagation studies or evaluations. These mobile systems, often battery-powered and weather-resistant, facilitate measurements in varied environments, contrasting with configurations that employ controlled antenna arrays and high-resolution analyzers for precise and long-term recording. Satellite-based detection, such as the Lightning Imaging Sensor (LIS) aboard the , which operated from 2017 to 2023, served as a global proxy by optically mapping lightning flashes that generate atmospheric noise, providing event counts and locations with detection efficiency around 60–70%. Noise level metrics are standardized using quasi-peak detectors, as defined in CISPR 16-1-1, to measure in decibels above one microvolt per meter (dBμV/m), accounting for the subjective impact of impulsive on receivers. This detector applies a charge-discharge to simulate human auditory perception, yielding values that correlate with practical communication degradation; for instance, atmospheric at VLF often exceeds 50 dBμV/m in tropical regions. Field strength calculations incorporate factors, with short vertical monopoles over planes serving as references for estimating median noise envelopes.

Impacts and Modeling

Effects on Radio Communications

Atmospheric noise interferes with radio communications primarily through impulsive broadband disturbances that raise the overall , significantly reducing the (SNR) in the (VLF, 3–30 kHz), (LF, 30–300 kHz), and (MF, 300 kHz–3 MHz) bands. These impulses, originating from discharges, manifest as non-Gaussian noise that superimposes on desired signals, leading to static crashes in amplitude-modulated (AM) broadcasts and signal fading due to the variable nature of the noise envelope. In these bands, the median atmospheric noise levels can exceed thermal noise by wide margins, often dominating the total noise budget and limiting reliable communication range and quality. The severity of these impacts varies geographically and temporally, with the highest noise levels occurring in tropical latitudes where thunderstorm activity is most intense, and during stormy seasons such as and summer when global rates peak. In contrast, effects diminish rapidly above 30 MHz, where atmospheric contributions become negligible compared to man-made and galactic noise sources, allowing higher-frequency systems like VHF and above to operate with less natural interference. To counteract these disruptions, several mitigation strategies are employed in affected radio systems. Diversity reception, which combines signals from multiple antennas or paths to combat fading induced by noise variability, improves reliability in LF and MF bands. Error-correcting codes, such as (FEC), help recover data corrupted by impulsive bursts, reducing bit error rates in digital communications. Frequency hopping spreads the signal across bands to evade localized noise peaks, particularly useful in and systems operating in noisy environments. Historically, atmospheric noise posed major challenges to early long-distance radio services, exemplified by disruptions in transmissions during the 1920s and , when thunderstorms caused severe static that overwhelmed signals and required elevated transmitter powers to maintain intelligibility. Measurements from that era indicated significant increases during intense storm activity, highlighting the limitations of pre-diversity era systems and spurring research into noise characterization by organizations like Bell Laboratories.

Statistical Modeling

Statistical modeling of atmospheric noise employs empirical distributions to characterize the nature of fluctuations and standardized frameworks to predict noise levels across geographic and temporal variations. variations, particularly for high-intensity events, are commonly represented by log-normal distributions, which effectively capture the deviation from statistics observed in large- regimes. This log-normal approximation arises from the impulsive character of noise bursts, where the logarithm of the follows a , enabling probabilistic assessments of exceedance levels. The CCIR/ITU models, notably CCIR Report 322 and its successor Recommendation P.372-17 (), provide comprehensive predictions of median atmospheric noise levels based on extensive global surveys. These models tabulate and chart the median available , expressed as F_{am} in above kT_0B (where k is Boltzmann's , T_0 = 290 , and B is ), varying systematically with , , time of day, and . For instance, noise levels are highest in tropical regions during summer months due to increased activity, with latitudinal gradients showing reductions of up to 20-30 toward polar areas. The models incorporate diurnal and seasonal multipliers to account for variability; nighttime levels are typically 10-20 higher than daytime equivalents, reflecting enhanced propagation of distant lightning-generated signals under ionospheric conditions prevalent after sunset. Seasonal effects further modulate these, with summer maxima in the often exceeding winter minima by 15 or more at mid-latitudes. The update enhances world charts for greater granularity in VLF/LF/ predictions. Key equations underpin these predictions, including the frequency dependence of noise power spectral density, approximated as S(f) \approx k \cdot f^{-\alpha}, where \alpha ranges from 1.5 to 2, capturing the observed roll-off in noise intensity at higher frequencies due to the broadband but decaying spectrum of lightning impulses. This form aligns with empirical fits to measured data across HF and VLF bands. For peak levels, cumulative distribution functions (CDFs) describe the probability that the noise envelope exceeds a threshold, often derived from amplitude-probability distributions (APDs), where the APD P(E > e) complements the CDF and follows a form like P(E > e) = \exp\left( -\frac{(\log e - \mu)^2}{2\sigma^2} \right) for log-normal fits, with parameters \mu and \sigma estimated from site-specific measurements. These distributions facilitate the computation of outage probabilities in communication systems. Validation of these models against measured data from global surveys, including over 50 recording stations worldwide, confirms their accuracy for median predictions, with typical error bounds of approximately 2 in the constructed noise maps. Comparisons reveal close agreement in mid-latitudes but larger discrepancies (up to 10 ) in high-latitude regions and certain arid zones, attributed to underrepresented local patterns in the original datasets. Updated analyses, such as those incorporating additional VLF/LF measurements, have refined the models to reduce these bounds, enhancing reliability for engineering applications.

Historical Development

Early Investigations

Early investigations into atmospheric noise, often referred to as "static" or "atmospherics," began in the late 19th and early 20th centuries as communication emerged. encountered significant interference during his transatlantic radio tests in the early 1900s, attributing the disruptive crackling sounds to associated with thunderstorms. These observations highlighted static as a major obstacle to reliable long-distance signaling, prompting early efforts to characterize the phenomenon. In the , researchers began recording (VLF) atmospherics to study their properties. A notable milestone was the work by W.H. Eccles and H. Morris Airey, who documented natural electrical waves in the VLF range using sensitive detectors, providing the first systematic recordings of these impulsive signals. By the , direction-finding techniques advanced the understanding of atmospheric noise origins. , working at the UK's Radio , employed cathode-ray oscilloscopes and antenna arrays to trace the of atmospherics, revealing correlations with distant discharges and establishing that the noise was not localized but originated from widespread thunderstorms across regions like and . These surveys demonstrated the global nature of the interference, influencing early theories on its propagation. A pivotal advancement came in 1932 with Karl Jansky's research at Bell Laboratories. Investigating interference for transatlantic telephony, Jansky used a rotatable merry-go-round to systematically map sources. He distinguished three types of static: local thunderstorms, distant thunderstorms, and a steady hiss from galactic origins, confirming thunderstorms as the primary atmospheric contributor distinct from extraterrestrial signals. This work, published in the Proceedings of the Institute of Radio Engineers, laid the groundwork for while solidifying the role of discharges in generating the bulk of observed atmospheric .

Modern Surveys and Standards

The CCIR Report 322, published in 1964 by the International Radio Consultative Committee, compiled extensive data from ground-based receiver stations worldwide during the 1950s and 1960s to produce global contour maps of median (VLF) atmospheric levels, differentiated by season and . These maps highlighted higher noise envelopes in tropical and subtropical regions during local summer months, with lower levels at higher latitudes and in winter seasons, providing a foundational for predicting in VLF and communications. The report emphasized seasonal variability, noting peak noise during periods of maximum activity, and included parameters for noise envelope Fa_m and variability metrics to support engineering applications. Subsequent evolution of ITU-R Recommendation P.372, which superseded earlier CCIR guidelines, incorporated refinements in the 1990s and 2010s, drawing on global lightning observations including from instruments such as the Optical Transient Detector (OTD, 1995–1997) and Lightning Imaging Sensor (LIS, launched 1997 on TRMM), which have informed improved prediction models in related . For instance, updates in P.372-10 (2009) and later versions enhanced spatial and of predictions, particularly for VLF affected by distant thunderstorms. The latest version, P.372-17 (), further refines these models with updated empirical data and expanded frequency coverage up to 100 GHz. Since the early 2000s, integration of from the World Wide Lightning Location Network (WWLLN), operational since 2003, has enabled dynamic forecasting of atmospheric noise by correlating stroke locations and intensities with interference patterns. WWLLN's global VLF supports near-real-time mapping of activity, allowing predictions of noise spikes for HF/VLF systems with temporal resolutions down to minutes. Recent surveys have also begun addressing measurement gaps, such as urban-rural variations in observed noise levels—where urban environments exhibit 10–20 higher total noise due to combined atmospheric and man-made sources compared to quiet rural sites—and potential increases in frequency linked to , projected to elevate global activity by up to 50% by 2100 under high-emission scenarios as estimated in a 2014 study.

Applications

Random Number Generation

Atmospheric noise provides a physical source of for true by capturing the unpredictable timings and amplitudes of radio impulses from distant sources, such as discharges, to produce non-deterministic bit sequences. These impulses, propagating through the atmosphere, exhibit chaotic variations that defy short-term prediction, making them suitable for seeding processes. A key implementation is the service, established in October 1998 by Mads Haahr at , which employs multiple FM-tuned radio receivers to sample atmospheric static between stations, generating raw random bits at rates of approximately 1,500 bits per second per receiver. Hardware random number generators, such as Intel's instruction introduced in , draw inspiration from physical entropy harvesting but rely on on-chip thermal noise rather than atmospheric signals, highlighting distinct approaches to achieving similar unpredictability. Entropy extraction from atmospheric noise often involves debiasing techniques to ensure , such as the von Neumann method, which processes sequential bit pairs—outputting the first bit if they differ and discarding matches—to eliminate bias from the source. Advanced sampling setups, like those using RTL-SDR devices, can extract randomness at high by digitizing noise and applying post-processing. Compared to pseudorandom number generators, which rely on deterministic algorithms and can be reproduced or predicted given the seed, atmospheric noise offers genuine unpredictability critical for , secure , and simulations. While the noise arises from phenomena that are theoretically deterministic, their extreme sensitivity to initial conditions ensures practical , rendering the output effectively for all foreseeable applications.

Meteorological and Scientific Uses

Atmospheric noise, particularly in the (VLF) range, plays a crucial role in networks by capturing electromagnetic pulses known as sferics generated by discharges. These networks utilize the propagation of VLF sferics through the Earth-ionosphere waveguide to locate strikes with high precision, enabling real-time tracking of thunderstorms. The U.S. National Lightning Detection Network (NLDN), operational since the 1980s and now comprising over 180 sensors as of 2024, detects cloud-to-ground events across , providing data that supports forecasting by the . This integration of noise-based detection has improved nowcasting of convective storms, allowing for timely warnings of hazards like flash floods and . In studies of the electric circuit (GEC), atmospheric noise serves as a for variations in the ionospheric potential, which is driven by worldwide thunderstorm activity. —electromagnetic waves in the (ELF) band excited by —exhibit intensities that correlate with the GEC's strength, reflecting changes in the fair-weather and ionospheric height. Researchers have linked these noise variations to global temperature fluctuations, suggesting potential integrations into models to assess atmospheric electrification's role in patterns. For instance, a 2025 study has used long-term monitoring of parameters to constrain activity trends and enhance predictability, revealing seasonal and influences on the GEC and aiding in the parameterization of electrified cloud effects in general circulation models. Correlations between VLF atmospheric noise perturbations and seismic activity have been investigated as potential pre-seismic signals since the early , focusing on ionospheric disturbances preceding earthquakes. These perturbations, observed as or anomalies in subionospheric VLF propagation, may arise from lithosphere-atmosphere-ionosphere coupling, such as emissions or altering the lower ionosphere's conductivity. Networks like the European VLF/LF radio system, established around 2010, have documented such anomalies up to days before moderate-to-large earthquakes, though causal links remain under debate and require further validation. Atmospheric noise analysis also supports ionospheric monitoring, particularly through the detection of sudden ionospheric disturbances () induced by s. VLF receivers capture enhanced signal propagation during , where emissions from flares increase D-region , altering noise levels and enabling real-time assessment of impacts. This method, documented since the mid-20th century but refined with modern networks, helps track intensities and their effects on the without relying on data alone. Such monitoring contributes to broader scientific research on solar-terrestrial interactions and forecasting.

References

  1. [1]
    None
    ### Summary of Atmospheric Noise from ITU-R P.372-13
  2. [2]
    [PDF] Atmospheric Radio Noise: Worldwide Levels and Other Characteristics
    ... Atmospheric Noise Measurement Locations. Corrections (dB) to CCrR Report 322 ... lightning that radiates these atmos- pherics radiates most of its ...
  3. [3]
    [PDF] RECOMMENDATION ITU-R P.372-7 - Radio noise*
    Radio noise external to the radio receiving system derives from the following causes: – radiation from lightning discharges (atmospheric noise due to lightning);.
  4. [4]
    [PDF] Sferics - NASA Technical Reports Server (NTRS)
    An atmospheric or more colloquially a "sferic" is the radio disturbance generated by a lightning discharge and modified by propagation influences during its ...
  5. [5]
    [PDF] Global Lightning Parameterization from CMIP5 Climate Model Output
    The global flash rate from OTD/LIS is 47 flashes per second. (consistent with Cecil et al. 2014), while the parame- terizations using C and M produce a ...
  6. [6]
    [PDF] Introduction to Interference Resolution, Enforcement and Radio ...
    Jun 10, 2014 · Another basic distinction associated with interference relates to RF noise. A general definition of RF noise is any undesired disturbances on a ...
  7. [7]
    [PDF] L` , I' AA CR-P2 - NASA Technical Reports Server (NTRS)
    Oct 26, 1971 · This distinction is maintained in the present report. Atmospheric and man made radio noise, like cosmic noise, are incoherent and therefore, add ...Missing: reliable | Show results with:reliable
  8. [8]
    [PDF] A Review of Low Frequency Electromagnetic Wave Phenomena ...
    Sferics and tweeks can be used to study the D-region of the ionosphere, tweeks provide information on the E and F-regions, and whistlers depend on the F-region ...
  9. [9]
    Introduction to VLF - Stanford VLF Group
    These are called radio atmospherics, or sferics. ELF/VLF waves also penetrate into seawater, which has led to their use over the past several decades for ...Missing: definition | Show results with:definition
  10. [10]
    None
    ### Summary of Atmospheric Noise from ITU-R P.372-15
  11. [11]
    A new VLF/LF atmospheric noise model - Fieve - AGU Journals - Wiley
    May 30, 2007 · This paper characterizes atmospheric noise in the 10–80 kHz range and proposes a new model: very accurate low-frequency noise model (VALERIE).Missing: spectrum | Show results with:spectrum
  12. [12]
    Natural atmospheric noise statistics from VLF measurements in the ...
    Oct 21, 2010 · In this paper we present atmospheric noise statistics based on VLF measurements at different temporal resolution (from minutes to seasonal variations).
  13. [13]
    [PDF] Very-low-frequency radiation spectra of lightning discharges
    The average value of energy calculated from the groundwave pulses was found to be 26,600 joules, which is lower than values derived from other experiments.
  14. [14]
    Sferics from intracloud lightning strokes
    Most of the large positive slow tails are generated by cloud-to-ground strokes. 3. Most of the smaller negative slow tails are generated by intracloud strokes.
  15. [15]
    Global frequency and distribution of lightning as observed from ...
    An analysis of this annual lightning distribution confirms that lightning occurs mainly over land areas, with an average land/ocean ratio of ∼10:1. The Congo ...
  16. [16]
    Sferics from lightning within a warm cloud - AGU Journals - Wiley
    UHF sferics in association with lightning discharges appear generally as trains of microsecond pulses lasting 10 or more microseconds.
  17. [17]
    [PDF] 14.3 Lightning Emissions—Greenhouse Gases
    range from 1.0 E+08 joules/flash to 8.0 E+08 joules/flash. 5. Because the first stroke in a lightning flash will release more energy than subsequent strokes,.
  18. [18]
    [PDF] RECOMMENDATION ITU-R P.372-8 - Radio noise*
    Radio noise external to the radio receiving system derives from the following causes: – radiation from lightning discharges (atmospheric noise due to lightning);.
  19. [19]
    2001-01-2933 : Precipitation-Static (P-Static) Overview of Composite ...
    Sep 10, 2001 · Streamer noise is caused by charge buildup on non-conductive vehicle frontal areas such as radomes and windshields. The spectral energy content ...
  20. [20]
    ELF Electromagnetic Waves from Lightning: The Schumann ... - MDPI
    The Schumann Resonances (SR) are global electromagnetic resonances excited within the Earth-ionosphere waveguide, primarily by lightning discharges. These ...
  21. [21]
    Investigation of the Reaction of Schumann Resonances to Short ...
    Aug 7, 2022 · A new method for calculating the parameters of Schumann resonance (SR) significantly reduces the impact of electromagnetic interference · The ...
  22. [22]
    Imprints of Intense Geomagnetic Storm on Very Low Frequency (VLF ...
    Jul 1, 2025 · Key findings include signal enhancement and attenuation of up to several tens of decibels during different phases of the storm's progression, ...
  23. [23]
    Radio wave emissions in the v.l.f-band observed near the auroral ...
    The v.l.f.-noise level was higher in the EW than in the NS direction, and this higher EW noise level was maintained during day and night for a year and also ...
  24. [24]
    Propagation of Electromagnetic Waves - Radartutorial.eu
    The ground wave is the preferred propagation type for long distance communication using frequencies below 3 MHz.Missing: noise mechanisms
  25. [25]
    Introduction to the Theory of VLF Propagation - ADS
    Wait, James R. Abstract. This paper is a self-contained exposition of the conventional theory of propagation of VLF radio waves. The model is a spherical earth ...
  26. [26]
    Review of mode theory of radio propagation in terrestrial waveguides
    The second and major part of the paper is devoted to the theory of the mode propagation of VLF radio waves. Here the effective waveguide is the space formed by ...
  27. [27]
    Daytime ionospheric D region sharpness derived from VLF radio ...
    May 17, 2011 · [1] We described and applied a technique to measure the local midlatitude daytime ionospheric D region electron density profile sharpness ...
  28. [28]
    [PDF] Modeling electromagnetic propagation in the earth-ionosphere ...
    At extremely low frequency (ELF: 3–3000 Hz) and very low frequency (VLF: 3–30 kHz), the ionosphere strongly affects propagation even over short paths. ELF-VLF ...Missing: noise | Show results with:noise
  29. [29]
    Daytime tweek atmospherics - Ohya - 2015 - AGU Journals - Wiley
    Dec 11, 2014 · The tweeks propagate in the Earth-ionosphere waveguide over long distances ( approximately several thousand kilometers). Tweeks are observed ...<|separator|>
  30. [30]
    A detailed investigation of low latitude tweek atmospherics observed ...
    In other words, these tweeks detected by our ELF/VLF receiver originate primarily from the lightning strikes that occur about 1000–4000 km away from Suizhou ...
  31. [31]
    Earth-Ionosphere Waveguide - an overview | ScienceDirect Topics
    The Earth-ionosphere waveguide refers to a propagation mechanism where VLF waves travel through multiple reflections between the Earth's surface and the lower ...
  32. [32]
    [PDF] ACCURATE AND EFFICIENT LONG-RANGE LIGHTNING GEO ...
    A new technique of long-range global lightning location is presented that both takes advantage of the efficient propagation at VLF and addresses the path- ...
  33. [33]
    Tools for VLF natural radio noise investigation in Yakutsk
    The antenna system of the receiver consists of two multi-turn crossed loop antennas, each having an effective area of 360 m2 and a vertical electric antenna ...
  34. [34]
    Ultra-sensitive broadband “AWESOME” electric field receiver for ...
    Feb 2, 2021 · In this paper, we present and describe an ultra-sensitive electric field receiver that enables broadband radio reception from near-DC up to 470 kHz.
  35. [35]
    APD oudoors time-domain measurements for impulsive noise ...
    This document presents a methodology to obtain the APD measurement at any frequency band employing two single time-domain oscilloscope captures. The ...Missing: atmospheric | Show results with:atmospheric
  36. [36]
    Performance Evaluation of the Lightning Imaging Sensor on the ...
    ISS LIS detects an average of 3.4–4.3 events per group within ±30° but roughly 3.0–3.2 within ±30°–40°. However, ISS LIS groups per flash show large values ...Abstract · Introduction · Instrumentation and data · Results
  37. [37]
    [PDF] Ionospheric propagation and noise characteristics pertinent to ... - ITU
    An early investigation of selective fading by the use of multi-tone signals on a transoceanic path was reported in the classic paper by Potter [1930]. Other ...
  38. [38]
    [PDF] Report ITU-R M.2411-0
    – Frequency diversity: frequency hopping (FH), wideband transmission, etc. – Code diversity: multiple PN codes, multiple FH code, etc. – Multi-user ...
  39. [39]
    The Future of Transoceanic Telephony - 1942 - Atlantic Cable
    Oct 2, 2019 · ... signal higher above the level of atmospheric noise. The influence ... One might visualize the broad-band transatlantic radio telephone ...
  40. [40]
    [PDF] AND HIGH-FREQUENCY ATMOSPHERIC RADIO NOISE IN ... - DTIC
    If the interference comes from a local source, apparent noise powers 10-15 dB higher than the atmospheric noise level can be expected. Under these circumstances ...
  41. [41]
    [PDF] Amplitude-probability distribution of atmospheric radio noise
    the variations of the level of atmospheric noise may be caused by a change in propagation conditions or lightning activity or both, and it has been an obstacle ...Missing: primary | Show results with:primary
  42. [42]
    P.372 : Radio noise
    ### Summary of Statistical Modeling of Atmospheric Radio Noise (ITU-R P.372)
  43. [43]
    Seasonal and Diurnal Dynamics of Radio Noise for 8–20 MHz ...
    Aug 31, 2022 · As one can see, the vertical absorption goes through a maximum at summer daytime. This corresponds well, qualitatively, to the D-layer ...
  44. [44]
    [PDF] A Discrepancy in the CCIR Report 322-3 Radio Noise Model ... - DTIC
    Use the CCIR Report 322-3 atmospheric noise model with caution, especially in the northern and southern high latitudes, the Arabian Peninsula, northern Africa, ...
  45. [45]
    [PDF] Atmospherics Steven Connor
    Development of Ear Wardens, An Electronic Device to Simulate Atmospheric Static. ... Early radio constituted an arduous, attentive, inventive labour of listening.
  46. [46]
    Guglielmo Marconi - Knowino
    Jun 24, 2011 · Passengers were soon sending telegrams by radio called "Marconigrams". ... atmospheric static. Finally, there had been no independent ...
  47. [47]
    [PDF] AN-006 - RDF Products
    This technique, developed by Sir R. A. Watson-Watt of Great Britain back in the 1920's, is the DF technique employed by most RDF Products DF ...<|control11|><|separator|>
  48. [48]
    [PDF] Karl Jansky and the beginning of Radio Astronomy
    Apr 27, 2023 · 18 January 1932: The peculiar thing about this static is that the direction from which it comes gradually changes and what is most.
  49. [49]
    [PDF] Documents of the CCIR (Geneva, 1963): Report 322
    All these types are considered here, but since atmospheric noise usually predominates at frequencies below about. 30 Mc/s, this Report deals primarily with this ...Missing: impact stormy MHz
  50. [50]
    [PDF] CCIR Report 322 Noise Variation Parameters. - DTIC
    CCIR Report 322 presents the predicted values of the median noise level (Fam) as one noise level contour map of the world for a frequency of 1 MHz, along with a ...Missing: 1964 | Show results with:1964
  51. [51]
    [PDF] A numerical representation of CCIR report 322 high frequency (3-30 ...
    ... report are average values of the noise to be expected in a given season of the year within discrete four-hour time blocks. A frequency dependence is given ...Missing: VLF | Show results with:VLF
  52. [52]
    LIS/OTD Gridded Lightning Climatology Data Sets - GHRC DAAC
    The LIS/OTD Gridded Climatology data sets consist of gridded climatologies of total lightning flash rates seen by the spaceborne Optical Transient Detector ( ...Missing: noise ITU- P. 372
  53. [53]
    WWLLN
    Welcome to WWLLN - the World Wide Lightning Location Network. A global network monitoring lightning activity over the entire Earth.WWLLN Global Lightning... · Station Spectrograms · The World Wide Lightning...Missing: atmospheric noise forecasting
  54. [54]
    Using the World Wide Lightning Location Network (WWLLN) to ...
    Jul 5, 2021 · We investigate a novel way to quantify Very Low Frequency transmission in the Earth-Ionosphere Waveguide, using data from the World Wide Lightning Location ...
  55. [55]
    P.372 : Radio noise - ITU
    Aug 26, 2024 · P.372 : Radio noise. Recommendation P.372-17 (08/2024). Approved ... Contact for this page : ITU-R Web coordinator. Updated : 2025-02-19. DCSIMG.<|control11|><|separator|>
  56. [56]
    (PDF) ED41C-0950: Real-time Lightning to Identify Sources of Noise ...
    Jan 5, 2024 · We investigate deep atmospheric convection in the global broad tropics, including case studies of tropical cyclones.
  57. [57]
    Changes in severe thunderstorm environment frequency during the ...
    This study addresses the question of how severe thunderstorm frequency in the United States might change because of enhanced global radiative forcing.
  58. [58]
    Introduction to Randomness and Random Numbers - RANDOM.ORG
    RANDOM.ORG is a true random number service that generates randomness via atmospheric noise. This page explains why it's hard (and interesting) to get a computer ...
  59. [59]
    Random numbers plucked from the atmosphere - The Irish Times
    Dec 4, 2018 · One source of randomness is atmospheric noise, the “static” generated by lightning discharges: world-wide, there are about 40 lightning flashes every second.
  60. [60]
    The History of RANDOM.ORG
    RANDOM.ORG is a true random number service that generates randomness via atmospheric noise. This page explains how RANDOM.ORG came about back in 1997.
  61. [61]
    Behind Intel's New Random-Number Generator - IEEE Spectrum
    Aug 24, 2011 · A new instruction, called RdRand, provides a way for software that needs random numbers to request them from the hardware that's producing them.
  62. [62]
    [PDF] Various Techniques Used in Connection With Random Digits - MCNP
    By John von Neumann. SUJnJnary written by George E. Forsythe. In manual computing methods today random control call for these numbers as needed. The real.
  63. [63]
    RTL-SDR as a Hardware Random Number Generator with rtl_entropy
    Jun 18, 2015 · The theory behind the RNG is by taking advantage of atmospheric noise ... At 2.8 Mbps it should take less than 2 hours to generate the test ...
  64. [64]
    National Lightning Detection Network (NLDN) - Vaisala
    The Vaisala National Lightning Detection Network (NLDN) detects more real-time lightning events than any other network with unrivaled location accuracy.
  65. [65]
    [PDF] The US National Lightning Detection Network - atmo.arizona.edu
    We describe the U.S. National Light- ning Detection NetworkTM (NLDN), a system that senses the electromagnetic fields that are radiated by individual return.
  66. [66]
    Severe Weather 101: Lightning Detection
    These two systems work by detecting radio waves (sferics) emitted by fast electric currents (strokes) in lightning channels. A “stroke” can be a fast current ...
  67. [67]
    Ionospheric potential as a proxy index for global temperature
    He also reported high correlation between monthly mean tropical surface air temperature and Schumann resonance measurements of global lightning activity.
  68. [68]
    [PDF] The European VLF/LF radio network to search for earthquake ...
    Since 2000 Japanese researchers have been relying on the ex- istence of a VLF radio network (Pacific network) of seven receivers able to measure the ...
  69. [69]
    Subionospheric VLF signal perturbations possibly related to ...
    Aug 1, 1998 · The seismic influence on the VLF signal is probably explained by the generation of long-period gravity waves during the earthquake process and ...
  70. [70]
    [PDF] Sudden Ionospheric Disturbance (SID) - NOAA
    Mar 23, 2014 · The ionospheric disturbance enhances VLF radio propagation. Scientists on the ground can use this enhancement to detect solar flares; by ...
  71. [71]
    Sudden Ionospheric Disturbances (SIDs) - aavso
    The AAVSO SID Program consists of solar observers who monitor very low frequency (VLF) radio stations for sudden enhancements of their signals.