Fact-checked by Grok 2 weeks ago

Regenerative circuit

A regenerative circuit is an electronic that utilizes , also known as regeneration, to dramatically boost the and selectivity of radio receivers by reinforcing weak incoming signals within a tuned , often using a single for both amplification and detection. Invented by American engineer Edwin Howard Armstrong in 1912 during his undergraduate studies at Columbia University, the regenerative circuit built upon Lee de Forest's audion vacuum tube and addressed key limitations in early wireless technology by maximizing gain from limited components. Armstrong patented the design in 1914 (U.S. Patent No. 1,113,149), earning recognition including the Institute of Radio Engineers' Medal of Honor in 1917 for its transformative role in radio amplification. Technically, the circuit operates by coupling a portion of the amplified output—typically via a "tickler" coil—back to the input resonant tank circuit (comprising an inductor and variable capacitor), which increases the circuit's quality factor (Q) and sharpens frequency response while the tube's nonlinear characteristics enable amplitude modulation (AM) demodulation. The invention sparked a prolonged patent dispute with de Forest, who claimed prior discovery of feedback effects; after over a decade of litigation, the U.S. ruled in de Forest's favor in , though Armstrong is widely credited as the true innovator by historians and engineers. Widely adopted in the for affordable shortwave and AM receivers due to its high performance with minimal parts and low power needs, the regenerative circuit laid foundational principles for subsequent advancements like superregenerative and superheterodyne designs, remaining influential in modern low-cost applications such as wireless sensors and experiments. However, it requires careful adjustment of to avoid , which can generate unintended transmissions and interfere with adjacent receivers.

Principles of operation

Basic feedback mechanism

A regenerative circuit employs , where a portion of the amplifier's output signal is fed back to its input in phase, reinforcing the input signal to achieve significantly higher and selectivity compared to non-regenerative amplifiers. This process, termed "regeneration," amplifies weak signals by recirculating energy within the , effectively multiplying the input multiple times before detection. Positive feedback differs fundamentally from : while subtracts the fed-back signal to stabilize and minimize —a concept invented by Harold S. Black at Bell Laboratories on August 2, 1927—positive feedback adds to the input, driving the toward instability and enabling dramatic signal enhancement near the threshold. In regenerative operation, the feedback is carefully adjusted to remain just below , where weak input signals are amplified exponentially without full , resulting in gains that can exceed 100,000 in early vacuum-tube implementations. This near-oscillatory regime exploits the amplifier's inherent nonlinearity to detect and amplify faint radio-frequency signals effectively. The overall voltage gain A in a regenerative amplifier is derived from the standard feedback equation for positive reinforcement: A = \frac{A_0}{1 - A_0 \beta} where A_0 is the open-loop amplifier gain and \beta is the feedback fraction (0 < \beta < 1). For stable amplification, the condition $1 - A_0 \beta > 0 (or loop gain A_0 \beta < 1) must hold; equality at A_0 \beta = 1 initiates sustained oscillation, beyond which the circuit no longer functions as an amplifier. This derivation follows from analyzing the input-output relationship in a feedback loop, where the effective input becomes the original signal plus the in-phase feedback contribution, leading to the denominator's reduction and thus gain magnification. When incorporated into tuned circuits, such as parallel LC resonators, regeneration enhances selectivity by boosting the effective quality factor Q, which measures the circuit's sharpness of resonance. The enhanced Q is approximated as: Q_{\text{regen}} \approx \frac{Q_0}{1 - A_0 \beta} where Q_0 is the unloaded Q-factor of the tank circuit, determined by its resistive losses. As feedback approaches the oscillation threshold (A_0 \beta \to 1^-), Q_{\text{regen}} increases dramatically—potentially by factors of 10 to 100—narrowing the bandwidth and improving rejection of off-frequency signals, though excessive regeneration risks instability and distortion. This Q-enhancement arises because the recirculating energy counteracts losses in the resonator, effectively reducing the equivalent series resistance in the circuit model.

Circuit configuration and gain enhancement

The standard configuration of a regenerative circuit utilizes a single vacuum tube, known as the in early implementations, featuring , plate (wing), and (cathode) electrodes. The circuit incorporates a tuned resonant network where the (RF) input signal is impressed, while the plate circuit includes an coil that couples back to the circuit for . This setup interlinks two resonant s—a circuit tuned by L and capacitance C, and a plate (wing) circuit with L'—connected at a common point via the , enabling amplification through energy transfer between them. Key components include a variable tickler serving as the secondary winding in the plate circuit to provide adjustable inductive to the primary grid , a regeneration such as a variable resistor in the grid circuit or a to fine-tune intensity, the input tuned for selective , and an integrated detector function within the for signal rectification. Additional s like radio chokes prevent energy from leaking into the power supply, and bypass (typically 2 µF) shunt high- oscillations to for stability. In operation, the RF input charges the grid , modulating the plate current and generating an in the plate L', which induces a reinforcing voltage in the grid via the transformer-like (often with a turns of 2:1). This loop circulates energy to amplify the signal, with the regeneration level adjusted just below threshold—controlled by varying the tickler or —to maximize while avoiding . Early designs operated with plate voltages ranging from 90 to 250 V to bias the effectively. The enhancement arises from the reducing the effective of the tuned circuit, thereby increasing its loaded Q-factor and sharpening selectivity, which improves the by concentrating energy on the desired frequency. This mechanism can boost overall detection by factors of 15,000 or more compared to non-regenerative amplifiers, enabling weak signal reception with minimal components. In modern low-power adaptations, the is supplanted by bipolar junction transistors (e.g., ) in a common-emitter configuration, where is applied from the collector to the base via a tapped or coupled mimicking the tickler , often in a two- or three-transistor setup for RF and audio output. Op-amp based versions, using devices like the LM741 in a loop with a tuned input, appear in educational kits to demonstrate principles without high voltages.

Regenerative receivers

Amplitude modulation reception

In (AM) reception, the signal consists of a whose is varied by the modulating , producing upper and lower sidebands that carry the . The regenerative circuit plays a crucial role by amplifying these weak (RF) signals prior to envelope detection, where the audio envelope is extracted from the modulated . This is achieved through in the receiver's tuned circuit, enhancing the overall signal strength without requiring multiple amplification stages. The operation of the regenerative circuit in AM reception relies on controlled to boost and sharpen selectivity, particularly effective for medium-wave broadcast bands spanning 530 to 1600 kHz. By feeding a portion of the amplified output back to the input, the circuit increases the effective Q-factor of the tuned circuit, allowing a single or stage to achieve performance comparable to multi-stage tuned (TRF) designs. The level is adjusted to just below the point of , maximizing sensitivity while maintaining stability for demodulating AM broadcasts. In a typical configuration, this involves a with the path coupled through a parallel-tuned . Following regeneration, the amplified signal is fed to an , such as a or a grid-leak detector, to recover the . In a grid-leak detector, the grid of the acts as the rectifier plate, where the RF signal charges a through a high-value (the grid leak), producing a negative voltage proportional to the signal ; this modulates the tube's conductivity to amplify the audio variations. The resulting audio-frequency output is then coupled via an to or a for reproduction. This process effectively translates the AM modulation into audible sound with minimal distortion when regeneration is properly controlled. Practical examples of regenerative circuits for AM include upgrades to 1920s crystal sets, where adding a single tube with regeneration enabled long-distance reception of broadcast stations using simple antennas. These one-tube receivers demonstrated typical sensitivities of 1-10 μV, sufficient to pull in weak signals from distant transmitters, rivaling more complex designs of the era. Tuning challenges in AM reception with regenerative circuits center on the need for precise of the to prevent , such as "howling" or , which produces audible tones and disrupts . Operators must carefully adjust the regeneration —often a or —to operate at the threshold of , a that requires practice to balance maximum against , especially in environments with varying loading.

Continuous wave and single sideband reception

Regenerative circuits excel in (CW) reception by operating in autodyne mode, where the pushes the into , effectively turning the single active device—typically a —into both a signal and a for mixing with the incoming CW carrier. This mixing produces an audible frequency that renders the pulses detectable as tonal variations in the audio output. In autodyne operation, the simultaneously amplifies the received signal and generates the local through the regenerative feedback loop, with the deliberately offset from the by 500 to 1000 Hz to yield a comfortable audio for interpretation. This offset is achieved by slight detuning of the circuit's resonant elements, ensuring the beat note falls within the human without requiring additional mixer stages. For single sideband (SSB) reception, the regenerative circuit functions via product detection, where the controlled oscillation reinserts a local carrier signal to demodulate the suppressed-carrier voice modulation, a technique well-suited to operations that proliferated after the widespread adoption of in the . The inherent high gain and sharpen the circuit's selectivity, effectively attenuating the opposite to minimize and in voice communications. Regeneration enhances the loaded Q-factor of the tuned proportionally to the , enabling narrow effective bandwidths of 50 to 500 Hz for signals, which provides exceptional selectivity for distinguishing closely spaced code transmissions in crowded bands. Many practical designs incorporate variable or switched capacitors to dynamically adjust the resonant , facilitating seamless mode switching between narrow filtering and broader response. A key limitation in SSB use arises from feedback-induced distortion, which degrades audio fidelity—particularly at high modulation depths—yielding less natural voice quality compared to reception, as the nonlinear operation near introduces harmonic artifacts.

Design advantages and limitations

Regenerative receivers provide exceptional and selectivity through mechanisms that amplify weak signals using minimal components, typically requiring only one active device such as a or . This simplicity enables low-cost construction and low power consumption, making them ideal for battery-operated applications and home building by amateurs. The loop enhances by factors of 1000 or more, significantly outperforming tuned radio frequency (TRF) receivers in weak signal reception while improving the . Quantitative benefits include effective selectivity gains through the multiplication of coil Q by the feedback factor, typically enhancing Q by 10 to 100 times and allowing clear separation of closely spaced signals with fewer stages. Despite these strengths, regenerative designs suffer from instability when feedback approaches the oscillation threshold, often resulting in squealing or erratic performance that demands precise operator adjustment. Operating near this point can cause the receiver to radiate , disrupting nearby devices and violating regulations in shared spectrum environments. Additional limitations include poor rejection without extra RF filtering stages and or overloading in the presence of strong signals, which degrade audio quality. Compared to superheterodyne receivers, regenerative circuits are far less complex and more economical but offer inferior image rejection and overall stability, rendering them unsuitable for modern high-fidelity broadcast applications. However, their low complexity and power efficiency maintain relevance in niche modern uses, such as low-data-rate (IoT) sensors where simplicity outweighs performance demands. Common mitigation techniques include throttle controls, such as variable capacitors or potentiometers, to finely tune regeneration and prevent , alongside shielding to minimize radiated interference and external RF pickup.

Superregenerative receivers

Operating principles

A superregenerative extends the regenerative by incorporating periodic to reset the loop, enabling repeated cycles of that achieve exceptionally high for ultra-weak signals. Unlike standard regeneration, which maintains continuous near the oscillation threshold, superregeneration introduces a mechanism that periodically interrupts this process, allowing the to relax and restart. This results in bursts of regenerative action, providing logarithmic-periodic where the effective is highly sensitive to input signal strength. The quenching mechanism relies on a low-frequency oscillator, typically operating in the audio to low RF range, that modulates the to alternate between and . This oscillator generates a quench signal—often sinusoidal or relaxation-based—that drives the circuit's from negative (permitting build-up) to positive (causing extinction), interrupting the RF loop and preventing sustained . Common quench frequencies range from 20 to 100 kHz, producing short bursts of regeneration that are much faster than the signal rate, thus preserving the input while enhancing detection of weak signals. In implementations, is achieved via a dedicated quench coupled to the RF stage or a separate oscillator stage, frequently using two vacuum tubes: one for the RF regenerative oscillator and another for generating the quench signal. Operation proceeds in repeating stages: during the build-up phase, the RF signal initiates in the oscillator as reinforces transients; this is followed by the quench phase, where the signal is extinguished through increased ; the cycle then repeats at the quench rate. The duration of the build-up time t_b before quenching determines the output , yielding logarithmic where stronger input signals shorten t_b and produce higher average output levels proportional to the logarithm of the input . Additionally, the receiver's is inversely proportional to the quench frequency, trading selectivity for in ultra-low-power designs.

Applications and performance characteristics

Superregenerative receivers found early applications in the for shortwave detection, leveraging their high sensitivity for and early wireless experiments. During , they were employed in proximity fuzes for shells and bombs, where their compact design and ability to detect Doppler-shifted signals from targets enabled reliable detonation at close range, significantly enhancing anti-aircraft effectiveness. In modern contexts, superregenerative receivers serve niche roles in low-power systems, particularly at frequencies like 433 MHz for openers, remote controls, and RFID readers in and tracking. As of 2025, recent advances include super-regenerative oscillator-based sensors for and millimeter-wave applications, enabling ultralow-power detection. Their simplicity and extreme sensitivity, reaching down to approximately 10^{-13} W (-100 dBm), make them suitable for battery-operated toys, sensors, and IoT wake-up receivers in body area networks and short-range . Commercial integrated circuits, such as superregenerative modules from Radiotronix, integrate these receivers for such applications, offering stable operation at low currents around 4.5 mA. Performance-wise, superregenerative receivers achieve extreme total gain of 120-140 dB through repeated quenching cycles, enabling single-stage amplification comparable to multi-stage superheterodyne designs, though this comes with broadband noise due to the wide reception bandwidth (typically 5-10 times the signal bandwidth). Selectivity is limited inherently but can be improved via intermediate frequency (IF) filtering or surface acoustic wave (SAW) devices, which enhance rejection of adjacent channels while maintaining sensitivity. Their power efficiency shines in battery-powered devices, with consumption as low as 0.18 nJ/bit in integrated CMOS implementations for wireless sensor networks. However, drawbacks include high susceptibility to false triggering in noisy environments from amplified thermal noise and limited data rates below 10 kbps in typical short-range setups, restricting them to simple modulation schemes like OOK rather than high-speed protocols. Compared to SAW-filtered superheterodyne receivers, superregenerative designs offer lower cost and power but selectivity and interference immunity.

Historical development

Invention and early innovations

The regenerative circuit emerged from early 20th-century experiments with technology, particularly the invented by in 1906. In August 1912, during laboratory work in , de Forest accidentally discovered effects while connecting the output circuit of an to its input, resulting in amplified signals and unintended described as "howling." This observation of regenerative amplification, initially an unintended byproduct of amplification attempts, led de Forest to note enhanced sensitivity in his detectors, though he struggled to control the and viewed it as a nuisance to be minimized through techniques. De Forest's notebook entry from August 6, 1912, explicitly records obtaining "regeneration or amplification, as well as sustained ," marking the first documented instance of in a circuit. Edwin Howard Armstrong, then an undergraduate at Columbia University, built upon these inadvertent discoveries with a systematic approach starting in 1912. Armstrong introduced controlled regeneration using a "tickler coil" in the plate circuit to feed a portion of the amplified signal back to the grid, dramatically increasing gain without the instability de Forest had encountered. He demonstrated this configuration publicly in 1914, lecturing on its ability to strengthen incoming signals remarkably, and detailed the circuit's receiving and transmitting applications in articles published in the Electrical Experimenter magazine. Armstrong filed a patent application for the regenerative circuit on October 29, 1913, emphasizing its utility as both an amplifier and oscillator, which laid the groundwork for practical radio receivers. Early commercial adoption followed swiftly, with A. H. & Company producing regenerative receiver sets based on Armstrong's design as early as 1915, including models like the that enabled clearer reception for amateur operators. During , military radios transitioned from simple crystal detectors to regenerative amplifiers using Audion tubes with feedback, enhancing signal detection in field communications and providing the selectivity needed for battlefield operations. By 1920, regenerative circuits had become integral to home radios, allowing enthusiasts to receive transatlantic broadcasts with unprecedented clarity using just a single tube, thus democratizing long-distance radio listening before the dominance of superheterodyne designs. Technical refinements in the mid-1910s shifted feedback mechanisms from , as in Armstrong's initial tickler coil, to capacitive methods that reduced and improved precision in compact receivers. These evolutions, including AT&T's 1915 enhancements to de Forest's for transcontinental , underscored the circuit's role in making radio technology accessible and reliable for both civilian and military use prior to more advanced architectures.

Patent disputes and legal outcomes

The primary patent dispute over the regenerative circuit centered on a protracted legal conflict between Edwin H. Armstrong and Lee de Forest, spanning from the 1910s to the 1930s. De Forest, who had patented the Audion vacuum tube in 1906 (US Patent 841,387), initially claimed priority for the feedback principle underlying regeneration based on his earlier work, but Armstrong's specific application in a radio receiver was detailed in his 1913 patent application, granted as US Patent 1,113,149 on October 6, 1914, which explicitly described the use of positive feedback to enhance signal gain. The contention arose when de Forest, upon learning of Armstrong's circuit in 1915, asserted that his 1914 "ultra-audion" configuration (later patented as US 1,507,016 and 1,507,017 in 1924) encompassed the same invention, leading to interference proceedings in the US Patent Office. Legal proceedings unfolded through multiple lawsuits and appeals, marked by initial successes for Armstrong followed by reversals favoring de Forest. In 1921, a district court ruled in Armstrong's favor in an infringement suit against de Forest, validating his and awarding damages, a decision upheld on in 1922. However, de Forest, supported by the , which had acquired rights to his patents, countersued in , where a district court in 1924 declared Armstrong's invalid for lack of novelty. The case escalated to the twice: in 1928, it denied to Armstrong's , and in the landmark 1934 decision in Radio Corporation of America v. Radio Engineering Laboratories (293 U.S. 1), the Court, in an opinion by Justice Benjamin Cardozo, affirmed de Forest's priority based on his 1912 evidence, upholding his patents and effectively nullifying Armstrong's claims to originality. Related litigation involved Armstrong's for superregeneration (US 1,424,065, issued July 25, 1922), which extended regenerative principles but faced similar challenges from in licensing disputes, though it was not directly overturned in the core case. The 1934 Supreme Court ruling awarded de Forest legal priority, allowing RCA to extend licensing control over regenerative technology for an additional decade and resulting in Armstrong forfeiting millions in royalties he had collected since 1914. Despite this, the decision spurred advancements in feedback applications, notably influencing Harold S. Black's 1927 patent for (US 2,102,671), which mitigated regenerative instability in amplifiers. The disputes established key precedents in , emphasizing the role of contemporaneous records in proving priority and highlighting tensions between individual inventors and corporate entities like RCA in radio's . De Forest received partial credit for enabling technologies, though the engineering community, including the , continued to recognize Armstrong's foundational contributions to the circuit's practical implementation.

References

  1. [1]
    Regenerative Radio Receivers - Stanford
    Jun 10, 2012 · A regenerative radio uses a single tube for amplification and detection, with positive feedback to increase gain and selectivity. The signal is ...
  2. [2]
    [PDF] MITOCW | radio_receivers
    Our goal is to understand how a basic radio circuit, called the regenerative circuit, works to pick out one frequency. This circuit was a breakthrough in ...
  3. [3]
    The Regenerative Circuit – Major Armstrong: Scientist, Technologist ...
    Apr 19, 2010 · Armstrong made his first momentous discovery, the regenerative circuit, eliminating the need for headphones and providing the foundation of many radio ...
  4. [4]
    Edwin Armstrong Invents the Regenerative Circuit
    American Edwin Armstrong Offsite Link invented and patented Offsite Link the regenerative circuit Offsite Link from his parents' home in Yonkers, New York.
  5. [5]
    None
    ### Summary of Key Content from https://aireradio.org/Superet_arms/storia%20della%20reazione.pdf
  6. [6]
    Harold Black and the negative-feedback amplifier - IEEE Xplore
    On August 2, 1927, Harold Black, a young Bell Labs engineer just six years out of college, invented the negative-feedback amplifier. Negative feedback soon ...
  7. [7]
    [PDF] Feedback Systems - Stanford University
    While Armstrong's regenerative amplifier neatly much solved the problem of obtaining large amounts of gain from vacuum tube amplifiers, a different problem ...
  8. [8]
    Feedback Systems - Electronics Tutorials
    Then if the loop gain is positive for any system the transfer function will be: Av = G / (1 – GH). Note that if GH = 1 the system gain Av = infinity and the ...
  9. [9]
    Regenerative Receivers | Tutorials on Electronics
    ... fidelity is nonlinear and requires careful analysis. Mathematical Foundation. The effective Q of a regenerative receiver is given by: Q e f f = Q 0 1 − k A.
  10. [10]
    US1113149A - Wireless receiving system. - Google Patents
    An audion wireless receiving system having a resonant wing circuit interlinked with a resonant grid circuit upon which the received oscillations are impressed.
  11. [11]
    [PDF] Regenerative Receiver Project - WB1GOF
    Dec 21, 2021 · Tickler coil – provides positive feedback, which leads to high gain and oscillation. ○. RFC – RF choke, keeps radio frequency energy out of ...
  12. [12]
    Build the Retro Regen Radio | Nuts & Volts Magazine
    Circuit gain and regeneration is controlled by varying the plate voltage of V1-A with potentiometer R3 and plate resistor R3. Capacitor C5 bypasses any ...
  13. [13]
    [PDF] High Performance Regenerative Receiver Design - ARRL
    Regeneration introduces a negative resistance into a circuit such that its net positive resistance is reduced. Since the circuit's selectivity, or Q, is equal ...
  14. [14]
    [PDF] A Three Transistor Receiver - ARRL
    2-Circuit diagram of three-transistor regenerative receiver. Fixed resistors are ½-watt composition. Capacitors marked with polarity are electrolytic; those ...
  15. [15]
    [PDF] Regenerative Receiver for Beginners - ARRL
    In addi- tion to increasing the gain, regeneration also greatly increases the selectivity or "Q" of the circuit. C12 controls the amount of regeneration. C6 ...Missing: formula | Show results with:formula
  16. [16]
    Regenerative Receiver: Regen Radio - Electronics Notes
    The regenerative receiver or regen radio provides a significant increase in gain and selectivity over the standard tuned radio frequency receiver.
  17. [17]
    regenerative detectors - QSL.net
    The grid-leak detector is a combination diode rectifier and audio-frequency amplifier. ... One Tube (6U8) Regenerative Receiver Project; New R.D.Keys, NA4G ...
  18. [18]
    regenerative receiver - AmplitudeModulation
    The aim in the regenerative detector is to make the product (α β) approach 1 so that the denominator ( 1 - α β ) becomes very small to give a very large value ...
  19. [19]
    [PDF] An Ultra-Simple Receiver For 6 Meters - ARRL
    Receiver sensitivity is around 1 µV. Builders can easily modify the radio to operate over a wide band of VHF. It is inexpensive (about $20), can be built ...
  20. [20]
    A GOOD REGENERATIVE RECEIVER WITH SIMPLE FINE TUNING
    The sensitivity is approximately 0.5 to 2 microvolts on all bands. S9 is 50 uV, S8 is 25 uV and so on. In practice, that means that you can receive CW ...
  21. [21]
    Rationalizing the Autodyne Receiver, January 1933, QST - RFCafe
    Apr 30, 2013 · It functions as a sort of combined local oscillator and amplifier for demodulating CW (Morse code) signals. Technical writing styles have not ...
  22. [22]
    regenerative radio receivers - Electronics Tutorials
    The radio described here is a two band short wave receiver which is both very sensitive and very portable. It receives AM, single sideband (SSB), and CW (code) ...Missing: μV | Show results with:μV
  23. [23]
    [PDF] All about regenerative receivers
    This 3-valve regenerative receiver from the mid 1920s was one of the many kit ... Regeneration has its limitations. Although the feedback control can often ...
  24. [24]
    [PDF] Access High Performance Regenerative Receiver Design
    Feedback Network: The heart of the regenerative receiver, providing the positive feedback that increases the gain. Precise control over this network is.
  25. [25]
    [PDF] Super - Regenerative Receiver
    Feb 18, 2025 · describing the limiting quench frequency in terms of the natural frequency and Q-factor of the tuned circuit. Through the factor. *S, the ...
  26. [26]
    [PDF] Superregeneration Revisited: From Principles to Current Applications
    Operating in this way, the SRO performs amplitude detection by translating amplitude modulation into quench frequency modulation. This idea can be ...
  27. [27]
    [PDF] RADIATION LABORATORY SERIES - American Febo Enterprises
    ... proximity fuze are the two c-w systems that have been most. \riclely used ... superregenerative receiver and as a pulsed transmitting oscillator so that ...
  28. [28]
    [PDF] Application of Super Regenerative Receiver Module
    Excellent RF performance from 30MHz up to 6GHz. 6. Extreme cost effectiveness to meet the budget of Super Regenerative Receiver Module. 2012 Yantel Corporation ...Missing: limitations | Show results with:limitations<|control11|><|separator|>
  29. [29]
    https://theelectronicgoldmine.com/products/g22483
  30. [30]
    http://www.diva-portal.org/smash/get/diva2:306374/FULLTEXT01.pdf
  31. [31]
    [PDF] Super-Regenerative Receiver (SRR) for short- range HF band ...
    This receiver gives good performance for short range wireless applications but is not suitable for GSM applications as its sensitivity and selectivity are ...
  32. [32]
    https://aireradio.org/Superet_arms/storia%20della%20reazione.pdf
  33. [33]
    Westinghouse Electric & Mfg. Co. v. De Forest Radio T. & T. Co., 21 ...
    1,113,149 was issued to Edwin H. Armstrong covering ostensibly the circuit known as the feed-back or regenerative circuit to be used in connection with the De ...
  34. [34]
    [PDF] THE OLD TIMER'S BULLETIN - Antique Wireless Association
    (Adams-Morgan and A. H. Grebe had been making Arm- strong sets pre-war, since 1915 and. 1916 respectively). 7. Page 8. For the period April through June their.
  35. [35]
    [PDF] Army radio communication in the Great War - MHS Blogs
    This set used a C valve in the receiver, connected as an RF amplifier with regenerative feedback to increase its gain and provide improved selectivity.
  36. [36]
    A Selected History of Receiver Innovations Over the Last 100 Years ...
    Oct 22, 2018 · As early models of the regenerative and super-regenerative radios were put into production, this challenge became apparent and required ...
  37. [37]
    Regenerative Receivers Using Capacitive Feedback - Radiomuseum
    Feb 9, 2014 · Some time ago, regenerative receivers using capacitive feedback through the internal plate to grid capacitance of a vacuum tube triode were ...
  38. [38]
    Radio Corporation v. Radio Laboratories | 293 U.S. 1 (1934)
    For the purpose of any controversy between Armstrong and De Forest, the validity of the patents must be accepted as a datum. Even for the purpose of a ...
  39. [39]
    DE FOREST UPHELD IN 'FEEDBACK' CASE; Cardozo, in Supreme ...
    In effect it was decided that Lee De Forest and not Edwin H. Armstrong was the original inventor. In this case, in which Chief Justice Hughes took no part, the ...
  40. [40]
    Teacher Background | IEEE Reach
    Sungook Hong, “A History of the Regeneration Circuit: From Invention to Patent · Litigation” puts Armstrong's regeneration circuit in technical perspective: ...