Fact-checked by Grok 2 weeks ago

Blocking oscillator

A blocking oscillator is a type of that generates narrow, repetitive pulses using a single amplifying device—such as a or —coupled to a that provides to initiate and sustain brief conduction periods. The operates by allowing the to conduct for a short duration, during which builds up in the transformer's core, followed by a longer "blocking" or phase where the device is biased off, enabling the flux to decay and recharge a timing , thus preventing continuous and producing waveforms like rectangular pulses or sawtooth patterns with spikes. First described in by F. Vecchiacci and detailed in the Proceedings of the Institute of Radio Engineers, the blocking oscillator relies on transformer-coupled feedback with low to achieve its intermittent operation, where conduction is triggered by or bias and terminates due to core saturation or charging. Early designs used vacuum tubes, but transistor-based versions emerged in the mid-20th century, adapting the same regenerative principles for solid-state applications. Blocking oscillators are classified into two primary types: monostable, which produce a single output in response to an external and require recycling (often used as one-shot pulse generators), and astable, which operate in a free-running to generate continuous pulse trains that can be synchronized for timing purposes. Key applications include pulse generation for time bases in sweep circuits, timing, frequency division in counters, and signal sharpening or selection in early electronic systems.

Overview and Principles

Definition and Basic Concept

A blocking oscillator is a generator that produces narrow s through provided by a and an amplifying element, such as a or . It functions as a type of , where the circuit relaxes into a state after each generation. The core concept revolves around the "blocking" mechanism, in which the self-disables shortly after initiating a , preventing continuous . In transistor-based designs, this occurs due to of the amplifying element, which depletes the base current and cuts off conduction. In implementations, a buildup of voltage across the grid or capacitors achieves the same effect, charging to a level that biases the tube into . This self-limiting action ensures the oscillator remains inactive for an extended period before it can be retriggered. Blocking oscillators can operate in monostable mode, generating a single output in response to an external , or in astable mode for free-running continuous trains, making them suitable for various timing and applications in circuits. Their output consists of asymmetric waveforms characterized by brief active periods of high-amplitude s followed by long quiescent intervals, often resembling rectangular or spiked forms suitable for initiating actions in other systems.

Key Operating Principles

The blocking oscillator relies on through a transformer winding, where the output signal from an is coupled back to its input, rapidly increasing the input signal amplitude and driving the amplifier into . This regenerative process ensures that a signal initiates the loop, leading to quick buildup of the output pulse. Magnetic core saturation in the plays a critical role in the self-limiting behavior, as the core reaches a point where it can no longer store additional , causing the to drop sharply and collapsing the . This feedback collapse transitions the into the "blocking" state, where the is , preventing continuous and enabling discrete pulse generation. The is determined by the time constants associated with the circuit's and , particularly the time of a through the transformer's secondary winding, which controls how long the sustains before occurs. These time constants ensure the duration is proportional to the stored energy and circuit parameters, allowing for adjustable output characteristics without external synchronization. During operation, energy is stored in the transformer's magnetic field as current flows through the primary winding, building up flux until saturation; upon feedback collapse, this stored energy is released, contributing to the sharp trailing edge of the pulse and resetting the circuit for the next cycle. This magnetic energy handling distinguishes the blocking oscillator's efficiency in generating high-voltage pulses from low-power sources.

Historical Development

Origins and Early Use

The blocking oscillator was first described in 1931 by F. Vecchiacci in "Oscillations in the Circuit of a Strongly Damped ," published in the Proceedings of of Radio Engineers (vol. XIX, pp. 856-872). It emerged in and as a specialized form of within the broader advancements in , particularly for generating non-sinusoidal pulses in radio and early television systems. This development aligned with the growing demand for reliable pulse circuitry during the era's expansion of broadcast , where vacuum tubes enabled compact, self-sustaining signal generation without complex multi-stage setups. During , blocking oscillators found significant early application in vacuum tube-based systems for generating precise timing signals in oscilloscopes and equipment. In installations, they served as master oscillators in synchronizers to produce trigger pulses for range measurement and sweep control, ensuring accurate pulse repetition rates essential for detecting distant targets. Similarly, in oscilloscopes, these circuits provided stable timing for display sweeps, supporting the analysis of transient signals in military electronics. Their ability to deliver high-current, short-duration pulses made them ideal for the demanding environments of wartime . The blocking oscillator evolved from earlier tuned-grid oscillator designs, such as those based on principles, to offer simpler construction and greater reliability in pulse generation. This progression emphasized tighter mechanisms and reduced component count, addressing limitations in stability and waveform control found in prior configurations during the period. By the , a key milestone occurred with their widespread adoption in television receivers for horizontal sweep circuits, where they synchronized line scanning to maintain image stability amid the post-war boom in .

Notable Patents and Inventors

One of the foundational patents related to blocking oscillators was filed by Alan Dower Blumlein in , specifically U.S. Patent 2,241,762 (issued 1941), which described thermionic valve circuits for television scanning employing transformer-coupled feedback in an oscillator configuration, including a blocking oscillator to generate saw-tooth waveforms for deflection coils. This design laid groundwork for the regenerative feedback mechanisms central to blocking oscillator operation by enabling precise control of discharge and recovery phases through . In the post-World War II era, U.S. Patent 2,690,510 (filed 1946, issued 1954) by Gordon D. Forbes detailed blocking oscillator circuits configured as monostable devices for pulse generation, utilizing a single with to produce isolated, triggered pulses suitable for timing applications. This patent emphasized the oscillator's ability to deliver sharp, low-duty-cycle pulses with minimal components, addressing needs in emerging electronic systems. RCA Corporation contributed significantly to blocking oscillator development in the 1940s for television receivers, as exemplified by U.S. Patent 2,358,297 (filed 1940, issued 1944) by Alda V. Bedford, which introduced a grid-biased blocking oscillator variant to enhance synchronization stability against supply voltage fluctuations. The design incorporated a positive bias derived from the anode supply to maintain consistent frequency, representing an early grid-blocking configuration tailored for reliable horizontal deflection in TV sets. These patents collectively improved upon earlier pulse circuits like multivibrators by prioritizing reliability through reduced to voltage variations and enhanced steepness; for instance, Bedford's innovation mitigated drift issues inherent in multivibrators, enabling more stable operation in high-precision timing without continuous power draw. Similarly, ' monostable approach offered superior isolation for triggered s, outperforming multivibrators in applications requiring low and efficiency.

Circuit Design

Essential Components

The essential components of a blocking oscillator include an or pulse , a switching , a timing , and a biasing , with a saturable often integrated into the . The autotransformer or pulse transformer serves as the core feedback element, featuring tightly coupled windings—typically primary, secondary, and auxiliary—to provide positive feedback to the input of the switching element while minimizing leakage inductance for efficient energy transfer. This transformer often incorporates a saturable core, which enables sharp pulse edges by rapidly reaching magnetic saturation, thereby terminating the conduction phase and contributing to the oscillator's pulse-generating capability. Typical designs use low inductance values, such as 0.5 mH for the primary winding, to ensure fast response times suitable for pulse widths in the range of 0.05 to 25 µs. The switching element, usually a (e.g., or ) in modern implementations or a (e.g., ) in earlier designs, acts as the active device that amplifies the signal and controls the intermittent conduction. It drives the circuit into during the active phase, with the choice of device influencing pulse current and efficiency; for instance, power MOSFETs like the MTP3N60E are selected for high-voltage handling up to 600 V. The timing capacitor, connected to the input of the switching , determines the oscillator's repetition rate by charging and discharging through the biasing , with its value setting the quiescent interval between . Typical values range from 0.01 µF to 0.1 µF, forming an that is large relative to the for stable operation. The biasing resistor, often placed in the input (e.g., or ), provides negative to maintain the switching element in during the blocking , with high resistance values ensuring slow discharge of the timing . Common values include 1 MΩ for tube-based or 50 kΩ to 220 kΩ in designs, which help establish the and prevent premature triggering.

Standard Configurations

The standard monostable configuration of a blocking oscillator employs a single active device, such as a or , coupled with a to form an inductive feedback loop. The transformer's secondary winding connects to the device's input terminal ( or ), providing , while the primary winding is inserted in the output path (collector or plate ). A is placed in parallel with the secondary winding or in the input to enable the blocking mechanism via gradual discharge, ensuring single- generation upon triggering. This layout creates a compact, self-contained suitable for pulse initiation without continuous oscillation. A diode-clamped variant modifies this basic setup by incorporating a in series with the emitter or path to isolate reverse currents and accelerate switching transitions. In this arrangement, the forward-biases during the active phase to allow current flow but blocks it afterward, clamping the voltage and providing a low-impedance discharge path that yields sharper edges compared to resistor-based timing. The remains central, with the diode enhancing efficiency by minimizing leakage currents during the off state. Conceptually, the of a blocking oscillator depicts a single-stage encircled by an inductive loop through the , often with bifilar windings on a high-permeability core for tight coupling and minimal leakage. Resistors may stabilize , but the core elements—amplifier, , and —define the relaxation-based structure. Single-ended configurations, using one active device, prioritize simplicity and are common for low-power designs, whereas push-pull setups incorporate two devices driving opposite halves of a center-tapped primary, enabling higher power handling and balanced output through alternating conduction.

Detailed Operation

Active Phase (Switch Closed)

In the active phase of a blocking oscillator, the cycle commences with the closure of the switch, represented by the active device (such as a ) entering conduction, often initiated by thermal noise or an external trigger pulse that overcomes the slight negative bias at the input. This triggering event allows initial current to flow through the primary winding of the , inducing a voltage in the secondary winding that provides to the input of the . The mechanism rapidly amplifies the signal, leading to an buildup of in the primary as the is driven further into . The increasing primary generates a rising voltage across the secondary, which reinforces the input signal, accelerating the conduction and producing a steep in the output pulse. During this period, the in the intensifies, storing energy. The active phase typically terminates either when the reaches magnetic , which abruptly limits further increase, or when the becomes insufficient to maintain device , causing the induced secondary voltage to collapse and end the . The duration of this active phase, denoted as T_{on}, is primarily determined by the time constant of the primary circuit and approximates T_{on} \approx \frac{L}{R}, where L is the primary inductance and R is the effective series resistance; this yields short pulse widths, typically in the range of microseconds, due to the rapid linear ramp of current post-initial buildup.

Blocking Phase (Switch Open)

In the blocking phase, following the termination of conduction due to core saturation or device desaturation at the end of the active phase, the switch—whether a or —enters , halting conduction and initiating a quiescent period. This arises from a reverse condition where the coupling , charged negatively during the prior conduction, maintains the control electrode (grid or base) voltage below the for operation, effectively blocking further until the recovers. In vacuum tube designs, the plays a key role by allowing minimal while providing a high-resistance path that sustains the negative , preventing premature retriggering amid or residual signals. Upon , the saturated in the transformer's collapses rapidly, generating a flyback voltage across the windings; however, the amplifier's state blocks this induced voltage from feeding back to initiate another cycle, ensuring stable quiescence. The timing capacitor then discharges through the bias resistor, exponentially restoring the control voltage toward its equilibrium level and preparing for the next conduction. This discharge is governed by the of the capacitor and resistor, which sets the duration of the blocking phase, T_\text{off}, typically much longer than the active phase duration T_\text{on} to achieve the low repetition rates characteristic of blocking oscillators.

Frequency and Waveform Generation

The repetition rate of a blocking oscillator is given by f = \frac{1}{T_\text{on} + T_\text{off}}, where T_\text{on} is the duration of the active and T_\text{off} is the duration of the blocking , with T_\text{on} \ll T_\text{off} resulting in a pulse-like output . This configuration ensures that the oscillator produces discrete pulses rather than a continuous , as the short T_\text{on} corresponds to rapid core saturation in the , while the extended T_\text{off} arises from the governing capacitor recharge. The output waveform consists of narrow positive pulses with a fast rise time, followed by a flat baseline during the blocking interval, yielding a low-duty-cycle signal suitable for timing applications. The pulse width is approximately equal to T_\text{on}, determined by the transformer's inductance and the switch's conduction time until saturation, while the duty cycle is typically low in standard designs, emphasizing the asymmetry of the phases. Frequency stability is influenced by temperature sensitivity in the core saturation threshold, which can shift T_\text{on} due to material property changes, and by supply voltage variations that alter the charging rate during T_\text{off}. These factors introduce jitter in the repetition rate, with core materials like nickel-zinc ferrites offering improved thermal coefficients as low as 0.1%/°C to mitigate such effects.

Applications and Uses

In Pulse Generation and Timing

The blocking oscillator functions as a simple, low-cost alternative to the monostable multivibrator, particularly in generating precise trigger s for digital logic applications, where an external input initiates a single output of controlled duration. In standalone mode, it operates as a triggered monostable , producing a narrow upon activation before returning to its stable state, making it ideal for one-shot timing functions. These circuits find widespread use in timing applications, including relay drivers, signal flashers, and early computer systems, where they generate pulses with widths typically between 1 and 100 μs to synchronize operations such as counter advancements or sequential logic steps. For instance, in relay timing, the oscillator delivers short bursts to control coil energization, ensuring reliable switching without continuous power draw, while in flashers, it modulates pulse repetition for visual indicators. In early computing contexts, such as divider circuits, the pulses facilitate clock-like timing for basic arithmetic and control functions. A primary advantage stems from the transformer's role in amplifying peak power output, allowing the circuit to drive high-impedance loads efficiently despite low average power consumption. This, combined with the minimal components required—typically a , , and —enhances portability and reduces manufacturing costs for embedded timing modules. Nevertheless, blocking oscillators exhibit limitations, notably timing arising from variations in component tolerances, such as values or , which can introduce inconsistencies in positioning. This is often addressed through with external reference , stabilizing the for applications demanding repeatable timing .

In Display and Communication Systems

Blocking oscillators played a significant role in (CRT) television systems during the mid-20th century, particularly in generating synchronized pulses for horizontal deflection and flyback timing. In early receivers, such as the 1949 19A11S model, a blocking oscillator employing a single tube was integrated into a resonant circuit to produce anti-phase sawtooth waveforms at approximately 15,750 Hz, enabling precise horizontal scanning synchronized with incoming horizontal sync pulses. This configuration allowed the oscillator to conduct briefly during the flyback period, charging and discharging capacitors to create linear deflection voltages from a modest supply, a technique common in designs from the 1940s through the 1970s. The blocking oscillator's ability to self-limit its conduction cycle ensured stable operation under varying sync conditions, contributing to reliable image in and early color sets. In radar and early communication systems, blocking oscillators were employed for to produce sharp, precisely timed essential for and reception. In pulsed applications, the single-swing variant served as a master oscillator, generating narrow pulses directly without additional shaping circuitry, which facilitated accurate timing in systems like airborne where rise times needed to align closely with synchronizing inputs. This made it suitable for communication links requiring controlled durations, such as in early -derived data transmission setups, where the oscillator's relaxation behavior ensured minimal distortion in envelopes. By the mid-20th century, these circuits were standard in "ancient" generators, providing needle-like for detection and in analog communication protocols. Blocking oscillators also found integration in oscilloscope trigger circuits for maintaining stable displays, leveraging their precise timing for sweep . This application highlighted their utility in visual instrumentation, where the oscillator's pulse generation prevented in repetitive waveforms observed on screens. The widespread adoption of digital alternatives in the late led to the decline of blocking oscillators in mainstream display and communication systems, as integrated circuits and phase-locked loops offered greater precision and stability without the need for vacuum tubes or discrete components. Nonetheless, their simplicity and historical efficacy sustain interest in niche applications, such as recreations of radar and television equipment.

Variations and Implementations

Vacuum Tube-Based Designs

Vacuum tube-based blocking oscillators represent early implementations of this circuit topology, emerging during the mid-20th century era for reliable pulse generation in electronic systems. These designs utilized gas-filled or high-s to achieve self-blocking action through mechanisms, providing robust performance in environments requiring precise timing without complex external . A common configuration employed thyratron tubes, such as the type 884 or 885, or grid-controlled vacuum tubes like triodes (e.g., 6J5), where blocking is facilitated by a that develops a negative voltage during operation, cutting off the tube after each pulse cycle. This , often valued around 1 MΩ in conjunction with a grid of 5000 pF for frequencies near 1 kHz, ensures stable recovery timing and amplitude control. In thyratron variants, the gas discharge provides sharp triggering, while grid control minimizes , making these suitable for high-current applications up to 300 mA at 16 V drop. Typical circuits featured grid-leak blocking, incorporating a high-value (e.g., 1 MΩ) to charge the grid capacitor and establish negative bias, combined with autotransformer via a laminated iron-core for tight and 180-degree phase shift. This single-swing arrangement, often using receiving-type triodes or pentodes, delivered high peak power outputs, such as 100 from a 6J5 , with efficiencies exceeding 50%. These designs excelled in high-power applications, including transmitters, where they generated pulses up to W (0.5 A at 100 V) for time base circuits, offering superior tolerance to voltage spikes through coupling and resistors that mitigated overshoot and ringing. For instance, time base implementations utilized a dual-tube setup with a blocking oscillator (V1) driving a trace generator (V2) for reception, leveraging the circuit's ability to produce stable saw-tooth waveforms essential for deflection systems. Despite their effectiveness, vacuum tube-based blocking oscillators suffered from significant drawbacks, including substantial heat generation due to high-power dissipation in the tubes and transformers, as well as large physical size from bulky iron-core components and high-voltage envelopes. Nonlinearities in tube characteristics also introduced frequency shifts and harmonic distortion, limiting operational frequencies to around 50 kHz for thyratron types and requiring careful tuning to avoid parasitic oscillations.

Solid-State Transistor Versions

Solid-state transistor versions of blocking oscillators employ bipolar junction transistors (BJTs), typically NPN or PNP types, as the active switching element in place of vacuum tubes. The circuit configuration features a pulse transformer with windings coupled between the transistor's collector and base to provide positive feedback, enabling rapid saturation during the active phase. A key component is the base timing capacitor, connected in series with the feedback path, which charges through the base resistor during conduction and subsequently develops a reverse bias voltage across the base-emitter junction, blocking further feedback and initiating the relaxation period. This setup allows for precise control of pulse width via the capacitor value and transformer inductance, as analyzed in early designs achieving pulse widths on the order of microseconds with minimal components. Compared to vacuum tube implementations, transistor-based blocking oscillators demonstrate substantial efficiency gains, operating at lower supply voltages (typically 5-12 V versus hundreds of volts for ) and consuming far less power due to the solid-state device's lower current requirements and absence of heating. Additionally, their reduced physical footprint—often fitting within a few square centimeters—facilitates into compact systems, marking a shift from the bulky, power-hungry designs of the era post-1960s. These attributes stem from the transistor's inherent scalability and reliability, enabling widespread adoption in discrete circuitry. Circuit variations enhance performance for specific needs; for instance, emitter-coupled arrangements, such as configurations, improve frequency stability by reducing sensitivity to beta variations and temperature fluctuations, making them suitable for consistent generation. While not fully integrated into standard ICs like the 555 (which uses timing instead of ), blocking oscillators can form hybrid modules combined with ICs for adjustable triggering in applications. In modern contexts, these circuits are utilized in simple (SMPS) prototypes, where the blocking action drives small transformers for efficient voltage conversion at low input powers, as seen in basic boost converters. They also feature in educational kits to illustrate relaxation oscillation principles through hands-on assembly of NPN-based generators, and in the popular "" circuit, a minimalist self-oscillating voltage booster that extracts additional energy from nearly depleted batteries to power low-current loads like LEDs.

References

  1. [1]
    [PDF] BLOCKING OSCILLATORS - World Radio History
    Blocking Oscillators serve a variety of uses in many applica- tions of modern electronic circuitry. As a result of their importance,.
  2. [2]
    [PDF] BLOCKING OSCILLATORS - CORE
    The purpose of this paper is to give a general survey of the principles of circuit operation, applications and design considerations of vacuum-tube blocking.
  3. [3]
    Pulse Circuits - Blocking Oscillators - Tutorials Point
    A blocking oscillator is a waveform generator that is used to produce narrow pulses or trigger pulses. While having the feedback from the output signal, it ...
  4. [4]
    Blocking Oscillator - Definition, Operation and Types - eeeguide.com
    Blocking Oscillator – Definition, Operation and Types: The output of an active device may be coupled back to the input through a pulse transformer.
  5. [5]
    None
    Below is a merged summary of the blocking oscillator principles from "Practical Oscillator Handbook" (1997) by Irving M. Gottlieb, consolidating all information from the provided segments into a single, comprehensive response. To maximize detail and clarity, I’ll use a table in CSV format to present the key principles, their descriptions, and page references across the different segments. Following the table, I’ll include additional notes, page references, and useful URLs as a narrative summary.
  6. [6]
    None
    Summary of each segment:
  7. [7]
    THE SET - Blocking Oscillator Theory - Early Television Museum
    Blocking oscillator transformers came in two flavors (horizontal and vertical) because they had to be designed and manufactured to oscillate at a rate equal to ...
  8. [8]
    https://patents.google.com/patent/US2241762A/en
  9. [9]
    Blocking oscillator circuits - US2690510A - Google Patents
    BLOCKING OSCILLATOR CIRCUITS Filed March 29, 1946 Patented Sept. 28, 1954 UNITED STATES PATENT 4OIFLFTIfCE `-BLOCKING :OSCILL'ATOR CIRCUITS .Gordon D. ,-Forbes, ...
  10. [10]
    Blocking oscillator - US2358297A - Google Patents
    BEDFORD BLOCKING OSCILLATOR Filed July 31, 1940 2 Sheets-Sheet 2 Patented Sept. ... Rca Corp Blocking oscillator. US2483431A * 1944-05-10 1949-10-04 Sperry ...
  11. [11]
    [PDF] and8024-d.pdf - onsemi
    There are many issues associated with the blocking oscillator. The first issue is that it can only be designed for a single voltage input, such as 120 VAC or ...
  12. [12]
    [PDF] Performance Analysis of a Blocking Oscillator used for Low Voltage ...
    acceptable value of between 0.05 us to 25 us specified for blocking oscillators. Key words: Blocking oscillator, pulse transformer, efficiency, time ... capacitor.
  13. [13]
    [PDF] Circuit Changes Involved in Converting to Color
    In this case the capacitor -. C, in conjunction with resistors, R, or. R. determine the frequency of the blocking oscillator. A 2.2-megohm re- sistor can be ...
  14. [14]
    US2816230A - Blocking oscillator circuit - Google Patents
    Thus, by provision of the invention, highly eflicient, reliable and stable circuit operation is provided. The regenerative action described and thus oscillation ...
  15. [15]
    None
    ### Summary of Astable Push-Pull Blocking Oscillator Circuit Configuration
  16. [16]
    Blocking oscillator - Integrated Publishing
    The transformer controls the pulse width because it controls the slope of collector current increase between points T0 and T1. Since TC = L / R , the greater ...
  17. [17]
    Blocking Oscillator - BrainKart
    May 14, 2017 · The BLOCKING OSCILLATOR is a special type of wave generator used to produce a narrow pulse, or trigger. Blocking oscillators have many uses, ...<|control11|><|separator|>
  18. [18]
    [PDF] SYNTHESIS
    TRANSISTOR BLOCKING OSCILLATOR. TIME BASE GENERATOR by. Harold G riffith Robb. A Thesis Submitted to the Faculty of the. DEPARTMENT OF ELECTRICAL ENGINEERING ih ...
  19. [19]
    https://digital-library.theiet.org/doi/pdf/10.1049/pi-b-2.1959.0229
  20. [20]
    Core Saturation Blocking Oscillator Control * 647
    The general principles of operation of the blocking oscillator have been described elsewhere.I. ,2 The blocking oscillator shown here is normally cut off ...
  21. [21]
    [PDF] The 1949 ADMIRAL 19A11S TELEVISION SET and the most ...
    It must be synchronized to horizontal sync pulses in the usual way. The two ... All of the deflection oscillator parts, including two blocking oscillator.
  22. [22]
    Television Horizontal Deflection Circuit | Horizontal Output Stage
    Horizontal Oscillator and AFC:​​ Being much narrower than vertical sync pulses, and occurring at a much higher rate, horizontal pulses are a lot more susceptible ...
  23. [23]
    Pulsed Radar - Electrical & Electronics Engineering
    Oct 3, 2023 · When a blocking oscillator is used as a master oscillator, the timing trigger pulses are usually obtained directly from the oscillator. When a ...Duplexer · Receiver · Synchronizers
  24. [24]
    [PDF] Vacuum-Tube Oscillators By William A. Edson - World Radio History
    At least one vacuum-tube oscillator is used in virtually every trans mitter or receiver for radio, television, and radar. Oscillators are, therefore, of ...<|separator|>
  25. [25]
    Transistor Blocking Oscillator Analysis - ADS
    A review of the basic principles of operation is given and simplified equivalent circuits are included. A rise time equation is given in terms of the circuit ...
  26. [26]
    [PDF] THE TRANSISTOR - SUCCESSOR TO THE VACUUM TUBE?
    In conclusion, it can be said that the TRAN. SISTOR is an adequate substitute for the vacuum tube with attractive improvements in power re quired, efficiency ...
  27. [27]
    How Transistors Replaced Vacuum Tubes - Lantek Corporation
    Apr 14, 2022 · Electronics Evolution: replacing bulky, heat-prone vacuum tubes with efficient, smaller transistors.
  28. [28]
    evolution of power supply and its application to electrical and ...
    A very small and low weight switching transformer is used in the blocking oscillator [3] section of the SMPS circuit. The output D.C voltage is controlled in ...