利用者:加藤勝憲/ダイナトロン発振器

Dynatron vacuum tube signal generator, 1931. It covered the range 1.8 to 15 MHz. The circuit was used in signal generators due to its frequency stability, which was compared to crystal oscillators

The dynatron oscillator circuit was also used as the local oscillator in early vacuum tube superheterodyne radio receivers, such as this 1931 Crosley model 122 seven tube radio.

電子工学において、ダイナトロン発振器は1918年にゼネラル・エレクトリック社のアルバート・ハル[1][2]によって発明された旧式の真空管電子発振器回路であり、初期の四極真空管における二次放出と呼ばれるプロセスによる負性抵抗特性を利用したものである[3][4][5][6]。[7] ダイナトロン発振回路は、1920年代から1940年代にかけて、ビート周波数発振器（BFO）、真空管ラジオ受信機の局部発振器、科学機器や試験機器として限定的に使用されたが、真空管における二次放出のばらつきのため、第2次世界大戦前後に廃れた[8][9][10][11]。

In electronics, ダイナトロン発振器, invented in 1918 by Albert Hull^[1][2] at General Electric, is an obsolete vacuum tube electronic oscillator circuit which uses a negative resistance characteristic in early tetrode vacuum tubes, caused by a process called secondary emission.^[3][4][5][6] It was the first negative resistance vacuum tube oscillator.^[7] The dynatron oscillator circuit was used to a limited extent as beat frequency oscillators (BFOs), and local oscillators in vacuum tube radio receivers as well as in scientific and test equipment from the 1920s to the 1940s but became obsolete around World War 2 due to the variability of secondary emission in tubes.^{[8][9][10][11]}

1939年にクレト・ブルネッティ（英語版）によって発明されたトランジトロン発振器[8]などの負性トランスコンダクタンス発振器[12][13]は、5極管または他の多極管真空管における負性トランスコンダクタンス（第2のグリッドの電圧の上昇によって引き起こされる一方のグリッド電極を通る電流の低下）に基づく同様の負性抵抗真空管発振回路である[5][14]。これらはダイナトロン回路[14]に取って代わり、1970年代まで真空管電子機器に採用されていた[8][10][11]。

Negative transconductance oscillators,^[8] such as the transitron oscillator invented by Cleto Brunetti in 1939,^[12][13] are similar negative resistance vacuum tube oscillator circuits which are based on negative transconductance (a fall in current through one grid electrode caused by an increase in voltage on a second grid) in a pentode or other multigrid vacuum tube.^[5] These replaced the dynatron circuit^[14] and were employed in vacuum tube electronic equipment through the 1970s.^[8][10][11]

ダイナトロン発振器とトランシトロン発振器は、発振を発生させるために フィードバックを使用せず、負性抵抗を使用しているという点で、多くの発振 回路とは異なる[4][6]。インダクタとコンデンサを接続した同調回路（共振回路） は、「ほぼ」発振器である。同調回路が電気抵抗をゼロにできれば、一旦発振が始まれば発振器 として機能し、連続した正弦波を発生させることができる[15]。しかし、実際の回路には避けられない抵抗があるため、外部電源がなければ、発振電流のエネルギーは抵抗の熱として放散され、発振はゼロまで減衰する[15]。

The dynatron and transitron oscillators differ from many oscillator circuits in that they do not use feedback to generate oscillations, but negative resistance.^[4][6] A tuned circuit (resonant circuit), consisting of an inductor and capacitor connected together, can store electric energy in the form of oscillating currents, "ringing" analogously to a tuning fork.^[16] If a tuned circuit could have zero electrical resistance, once oscillations were started it would function as an oscillator, producing a continuous sine wave. But because of the inevitable resistance inherent in actual circuits, without an external source of power the energy in the oscillating current is dissipated as heat in the resistance, and any oscillations decay to zero.^[16]

ダイナトロン回路とトランシトロン回路では、真空管は、その電極の一方が負の微分抵抗を持つようにバイアスされる[4][6]。 これは、カソードに対する電極上の電圧が増加すると、それを通る電流が減少することを意味する[4]。同調回路は、電極とカソードの間に接続される。チューブの負性抵抗は同調回路の正性抵抗を相殺し、実質的に交流抵抗ゼロの同調回路を作る[6][15]。同調回路の共振周波数で自発的な連続正弦波発振電圧が生成され、それがオンになったときに回路内の電気ノイズによって開始される[15]。

In the dynatron and transitron circuits, a vacuum tube is biased so that one of its electrodes has negative differential resistance.^[4][6] This means that when the voltage on the electrode with respect to the cathode is increased, the current through it decreases.^[4] A tuned circuit is connected between the electrode and the cathode. The negative resistance of the tube cancels the positive resistance of the tuned circuit, creating in effect a tuned circuit with zero AC resistance.^[6][16] A spontaneous continuous sinusoidal oscillating voltage at the resonant frequency of the tuned circuit is generated, started by electrical noise in the circuit when it is turned on.^[16]

これらの発振器の利点は、負性抵抗効果が周波数にほとんど依存しないことであり、同調回路に適切な値のインダクタンスとキャパシタンスを使用することにより、数ヘルツから約20MHzまでの広い周波数範囲で動作することができた[6][8][9]。もう1つの利点は、ハートリー回路やアームストロング回路などの発振器で必要とされるタップや「ティクラー」コイルを使用せずに、単純な単一のLC同調回路を使用することであった[16]。

An advantage of these oscillators was that the negative resistance effect was largely independent of frequency, so by using suitable values of inductance and capacitance in the tuned circuit they could operate over a wide frequency range, from a few hertz to around 20 MHz.^[6][8][9] Another advantage was that they used a simple single LC tuned circuit without the taps or "tickler" coils required by oscillators such as the Hartley or Armstrong circuits.^[17]

In the dynatron a tetrode tube is used.^[4] In some tetrodes the plate (anode) has negative differential resistance, due to electrons knocked out of the plate when electrons from the cathode hit it, called secondary emission.^[4][5] This causes a downward "kink" in the plate current vs. plate voltage curve (graph below, grey region) when the screen grid is biased at a higher voltage than the plate, as described below. This negative resistance was mostly a feature of older tubes, of 1940s or earlier vintage.^[4] In most modern tetrodes, to prevent parasitic oscillations the plate is given a coating which drastically reduces the unwanted secondary emission, so these tubes have virtually no negative resistance "kink" in their plate current characteristic, and cannot be used in dynatron oscillators.^[4]

The tetrode wasn't the only tube which could generate dynatron oscillations. Early triodes also had secondary emission and thus negative resistance, and before the tetrode was invented they were used in dynatron oscillators by biasing the control grid more positive than the plate.^[1][18] Hull's first dynatron oscillator in 1918 used a special "dynatron" vacuum tube of his own design (shown above), a triode in which the grid was a heavy plate perforated with holes which was robust enough to carry high currents.^[2] This tube saw little use as standard triode and tetrodes could function adequately as dynatrons. The term "dynatron" came to be applied to all negative resistance oscillations in vacuum tubes; for example the split-anode magnetron was said to work by "dynatron oscillation".

An advantage of the dynatron circuit was that it could oscillate over a very wide frequency range; from a few hertz to 20 MHz.^[6][8][9] It also had very good frequency stability compared to other LC oscillators of that time, and was even compared to crystal oscillators. The circuit became popular after the advent of cheap tetrode tubes such as the UY222 and UY224 around 1928.^[9][17] It was used in beat frequency oscillators (BFOs) for code reception and local oscillators in superheterodyne receivers^[17] as well as in laboratory signal generators and scientific research. RCA's 1931 prototype television used two UY224 tubes as dynatron oscillators to generate the vertical deflection (28 Hz) and horizontal deflection (2880 Hz) signals for the CRT's deflection coils.

However the dynatron had some drawbacks. It was found that the amount of secondary emission current from the plate varied unpredictably from tube to tube, and also within a single tube over its operating life;^[19][20] eventually it would stop oscillating. When replacing the tube, several might have to be tried to find one that would oscillate in a circuit. In addition, since dynatron oscillations were a source of instability in amplifiers, the tetrode's main application, tube manufacturers began applying a graphite coating to the plate which virtually eliminated secondary emission.^[4] By 1945 the use of the dynatron circuit was declining.^[10][11][20]

Plate current (I_b) vs plate voltage curves for tetrodes:

An early tetrode, the RCA 24-A from 1929, showing on the lefthand side the negative resistance "kink" in the curves due to secondary emission. At a screen voltage V_C2 of 90 V it has negative resistance between about V_p = 10 to 60 V.

A modern tetrode, the 6P25. Due to a coating on the plate, there is very little secondary emission, so there is virtually no negative resistance region ("kink") in the curves, making this tube unusable for dynatron operation.

In an electron tube, when electrons emitted by the cathode strike the plate, they can knock other electrons out of the surface of the metal, an effect called secondary emission.^[4][5][19] In a normal tetrode amplifier this is an unwanted effect, and the screen grid next to the plate is biased at a lower potential than the plate, so these secondary electrons are repelled and return to the plate due to its positive charge.

However, if the screen grid is operated at a higher potential than the plate, the secondary electrons will be attracted to it, and return to ground through the screen grid supply.^[4] This represents a current of electrons I_G2 away from the plate, which reduces the net plate current I_P below the cathode current I_C

${\displaystyle I_{P}=I_{C}-I_{G2}\,}$

Higher plate voltage causes the primary electrons to hit the plate with more energy, releasing more secondary electrons. Therefore, starting at the voltage at which the primary electrons have enough energy to cause secondary emission, around V_P = 10V, there is an operating region (grey) in which an increase in plate voltage causes more electrons to leave the plate than the additional electrons arriving at the plate, and therefore a net reduction in plate current.

Since in this region an increase in plate voltage causes a decrease in plate current, the AC plate resistance, that is the differential output resistance of the tube, is negative:

${\displaystyle r_{P}={\Delta V_{P} \over \Delta I_{P}}<0\,}$

As with other negative differential resistance devices like the tunnel diode, this negative resistance can be used to create an oscillator. A parallel tuned circuit is connected in the plate circuit of the tetrode. The circuit will oscillate if the magnitude of the negative plate resistance is less than the parallel resistance R of the tuned circuit, including any load connected to the oscillator.

${\displaystyle |r_{P}|<R\,}$

The frequency of oscillation is close to the resonant frequency of the tuned circuit.

${\displaystyle f={1 \over 2\pi }{\sqrt {1 \over LC}}\,}$

As can be seen from the graphs, for dynatron operation the screen grid had to be biased at a considerably higher voltage than the plate; at least twice the plate voltage. The plate voltage swing is limited to the negative resistance region of the curve, the downward "kink", so to achieve the largest output voltage swing, the tube should be biased in the center of the negative resistance region.

The negative resistance of older tetrode tubes was around 10kΩ - 20kΩ, and can be controlled by varying the control grid bias. If the magnitude of the negative resistance |r_P| is just small enough to start oscillation, just a little smaller than the positive resistance R of the tuned circuit, the oscillation frequency will be very stable, and the output waveform will be almost sinusoidal. If the negative resistance is made significantly smaller than the positive resistance, the voltage swing will extend into the nonlinear part of the curve, and the peaks of the sine wave output will be flattened ("clipped").

The transitron oscillator, invented by Cledo Brunetti in 1939,^[12] (although a similar effect was observed in tetrodes by Balthasar van der Pol in 1926,^[21] and Edward Herold described a similar oscillator in 1935^[22]) is a negative resistance oscillator circuit using a pentode vacuum tube, in which, instead of the plate, the screen grid has negative resistance due to being coupled to the suppressor grid.^[5][19] See the circuit at right. In the transitron, the screen grid is biased at a positive voltage (battery B1) above the plate voltage while the suppressor grid is biased negatively (battery B2), at or below the cathode voltage. Therefore, all the electrons will be reflected by the negative suppressor grid and none will get through to the plate. The reflected electrons will instead be attracted to the screen grid, so the screen current will be high while the plate current will be zero. However, if the suppressor grid voltage is increased, as it approaches zero (the cathode voltage) electrons will begin to pass through it and reach the plate, so the number diverted to the screen grid, and thus the screen current, will decrease. Since the other grids don't take significant current the cathode current ${\displaystyle \scriptstyle I_{\text{C}}}$ is split between the plate ${\displaystyle \scriptstyle I_{\text{P}}}$ and the screen grid ${\displaystyle \scriptstyle I_{\text{G2}}}$:

${\displaystyle I_{\text{G2}}=I_{\text{C}}-I_{\text{P}}\,}$

The division of current between the screen grid and plate is controlled by the suppressor voltage. This inverse relationship is indicated by saying the transconductance between the screen and suppressor grid (the change in screen current ΔI_G2 divided by the change in suppressor voltage ΔV_G3) is negative.

Since the suppressor grid voltage and not the screen grid voltage controls the screen current, if the suppressor and screen grid are coupled together with a capacitor (C2) so there is a constant potential difference between them, increasing the screen grid voltage will increase the suppressor voltage, resulting in a decrease in screen current. This means the screen grid has negative differential resistance with respect to the cathode, and can be used to create oscillations.

In the transitron circuit, the screen and suppressor grids are coupled with a bypass capacitor (C2) which has a low impedance at the oscillation frequency, so they have a constant potential difference. The parallel tuned circuit (C1-L) is connected between the screen grid and the cathode (through battery B1). The negative resistance of the screen grid cancels the positive resistance of the tuned circuit, causing oscillations. As in the dynatron oscillator the control grid can be used to adjust the negative resistance.

Since the transitron oscillator didn't depend on secondary emission it was far more reliable than the dynatron. However, because the screen grid is not designed to handle high power, the oscillator's output power is limited. Other tubes with multiple grids beside the pentode, such as the hexode and pentagrid converter tube, have been be used to make similar negative transconductance oscillators. Pentode tubes used in this circuit have a negative transconductance of only around -250 microsiemens, giving a negative resistance of -4000Ω. Tubes with more grids, such as the pentagrid converter, can be used to make transitron oscillators with higher transconductance, resulting in smaller negative resistance.

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