利用者:加藤勝憲/サットン管

サットン管（Sutton tube）あるいは、リフレックス・クライストロン（reflex klystron）は、マイクロ波を発生させるための真空管。低消費電力で、当初は2つの用途で使われた。ひとつはマイクロ波帯域用受信機の局部発信器として。もうひとつは、別のマイクロ波源をオン・オフするスイッチとして、わずかな改良を加えて使用された。第二の用途は、ソフトサットン管（soft Sutton tube）やルンバトロンスイッチ（rhumbatron switch）^[1]として知られることもあり、第二次世界大戦中に英国が開発したマイクロ波レーダーの主要部品となった。これらを含むあらゆる設計のマイクロ波スイッチは、一般にT/R管またはT/Rセルとして知られている。

サットン管は、発明者の一人である真空管設計の専門家ロバート・サットンにちなんで命名された。クライストロンの原型は1930年代後半に米国で開発されたもので、サットンは調整可能なバージョンの開発を依頼された。彼は、アドミラルティ信号レーダー局で働きながら、1940年末に最初のモデルを開発した。サットン管は、第二次世界大戦中から1960年代まで、さまざまな形で広く使用された。その後、その役割は、1970年代に利用され始めたガン・ダイオードのようなソリッドステートデバイスに引き継がれた。「ルンバトロン」とは、多くのクライストロンに搭載されていた空洞共振部のことで、電子がダンスのルンバのように動くことにたとえて、そう呼ばれた。

クライストロンの基本仕様[編集]

Klystrons share the basic concept that the microwave output is generated by progressively accelerating then slowing electrons in an open space surrounded by a resonant cavity. The easiest klystron designs to understand have two cavities.

The first cavity is connected to a source signal, and is designed to resonate at the desired frequency, filling its interior with an oscillating electric field. The cavity's dimensions are a function of the wavelength, most are flat cylinders the shape of a hockey puck of varying sizes. A hole is drilled through the middle, at the center of the "puck".^[2]

A stream of electrons fired from an electron gun passes through the hole, and the varying field causes them to either accelerate or decelerate depending on the value of the rapidly varying field at the time they pass. Beyond the cavity the accelerated electrons catch up to the decelerated ones, causing the electrons to bunch up in the stream. This causes the stream to re-create the original signal's pattern in the density of the electrons. This area of the tube has to be fairly long to allow time for this process to complete.^[3]

The electrons then pass through a second cavity, similar to the first. As they pass, the bunches cause a varying electric field to be induced in the cavity, re-creating the original signal but at much higher current. A tap point on this cavity provides the amplified microwave output.^[3]

局部発振器[編集]

The introduction of the cavity magnetron caused a revolution in radar design, generating large amounts of power from a compact and easy-to-build device. However, it also required several additional developments before it could be used.

Among these was a suitable local oscillator about 45 MHz different than the transmitter signal, which fed the intermediate frequency section of the receiver circuits.^[4] The problem was that the magnetron's frequency drifted as it warmed and cooled, enough that some sort of tuneable microwave source was needed whose frequency could be adjusted to match. A second magnetron would not work, they would not drift in sync.

As the receiver circuit requires only very little output power, the klystron, first introduced only two years earlier, was a natural choice. Sutton, a well-known expert in tube design, was asked if he could provide a version that could be tuned across the same range as the magnetron's drift.^[5] An initial model available in 1940 allowed tuning with some effort. While it worked, it was not suitable for an operational system. Sutton and Thompson continued working on the problem, and delivered a solution in October 1940.^[4] Thompson named it for Sutton, while Sutton referred to it as the Thompson Tube. The former stuck.

Their advance was to use a single resonator and clever physical arrangement to provide the same effect as two cavities. He did this by placing a second electrode at the far end of the tube, the "reflector" or "repeller", which caused the electrons to turn around and start flowing back toward the gun, similar to the Barkhausen–Kurz tube. By changing the voltage of the reflector relative to the gun, the speed of the electrons when they reached the cavity the second time could be adjusted, within limits. The frequency was a function of the velocity of the electrons, providing the tuning function.^[5]

This modification effectively folded the klystron in half, with most of the "action" at the center of the tube where the input and output from the single cavity were located. Furthermore, only the interior of the cavity was inside the tube, the outer surface was in the form of a metal shell wrapped around the tube. Larger changes to the frequency could be made by replacing the outer shell, and this also provided a convenient location for mounting.^[5]

Unfortunately, the system needed two high-voltage power supplies, one for the initial acceleration in the gun, and a second between the gun and the reflector. And, due to the way it worked, the system was generally limited to milliwatts of power.^[要出典]

Soft Sutton tube[編集]

One of the advantages of using microwaves for radar is that the size of an antenna is based on the wavelength of the signal, and shorter wavelengths thus require much smaller antennas. This was vitally important for airborne radar systems. German aircraft, using longer wavelengths, required enormous antennas that slowed the aircraft between 25 and 50 km/h due to drag. Microwaves required antennas only a few centimetres long, and could easily fit within the aircraft nose.

This advantage was offset by the lack of a switching system to allow a single antenna to act as both a transmitter and receiver. This is not always a major problem; the Chain Home system made do with two sets of antennas, as did early airborne radars like the Mk. IV. In 1940 Bernard Lovell developed a solution for microwave radar by placing two sets of dipoles in front of a common parabolic dish and placing a disk of metal foil between them. However, this was not terribly successful, and the crystal diodes used as detectors frequently burned out as the signal bled through or around the disk.^[6] A solution using two spark gap tubes was also used, but was less than ideal.^[7]

A better solution was suggested by Arthur H. Cooke of the Clarendon Laboratory, and production development was taken up by H.W.B. Skinner along with A.G. Ward and A.T. Starr at the Telecommunications Research Establishment.^[7] They took a Sutton tube and disconnected the electron gun and reflector, leaving just the cavity. This was filled with a dilute gas, initially helium or hydrogen,^[8] but eventually settling on a tiny amount of water vapour and argon.^[9]

When the transmission signal was seen on the input, the gas would rapidly ionize (helped by a heater coil or radium). The free electrons in the plasma presented an almost perfect impedance source, blocking the signal from flowing to the output. As soon as the transmission stopped, the gas de-ionized and the impedance disappeared very rapidly.^[8] The tiny echoes caused by reflections from the target, arriving microseconds later, were far too small to cause the ionization, and allowed the signal to reach the output.^[4]

The usable soft Sutton tube arrived in March 1941, and was put into production as the CV43.^[4] It was first used as part of the AI Mk. VII radar, the first production microwave radar for aircraft.^[8] The system was widely used from then on, appearing in almost all airborne microwave radars, including the H2S radar and ASV Mark III radar.^[8]

Post-war intelligence revealed that the Germans were baffled by the purpose of the soft Sutton tube. Several examples fell into their hands, notably in the Rotterdam Gerät, an H2S that was captured in fairly complete form in February 1943. Interviews with German radar engineers after the war demonstrated that they could not understand the purpose of the unpowered tube.^[7]

The soft Sutton tube was used in a circuit known as a "T/R switch" (or many variations on that theme). Other spark tubes had been used for this purpose, in a design known as the "Branch-Duplexer". This consisted of two short lengths of waveguide about 1/4 of a wavelength, both of which turned on when the signal arrived. Because of the geometry of the layout, the two paths resulted in a reflection of the signal. Sutton tubes were used in a simpler design known as the "shunt branching circuit", which was T shaped with the transmitter and antenna located at either end of the horizontal portion of the T, and the receiver at the end of the vertical portion. By locating the Sutton tube at the right location along the waveguide to the receiver, the same effect as the branch-duplexer could be arranged.

脚注・出典[編集]

脚注[編集]

出典[編集]

表 話 編 歴 電子部品
半導体デバイス	MOSトランジスタ BiCMOS BioFET en:Chemical field-effect transistor (ChemFET) CMOS HMOS FinFET 浮遊ゲートMOSFET (FGMOS) 絶縁ゲートバイポーラトランジスタ (IGBT) ISFET en:LDMOS MOSFET MuGFET NMOS PMOS パワーMOSFET 薄膜トランジスタ (TFT) en:VMOS 他のトランジスタ バイポーラトランジスタ (BJT) 拡散接合トランジスタ ダーリントントランジスタ（英語版） 電界効果トランジスタ (FET) 電界効果テトロード en:JFET en:Light-emitting transistor (LET) 有機電界効果トランジスタ (OFET) en:Organic light-emitting transistor (OLET) en:Pentode transistor 点接触型トランジスタ ユニジャンクショントランジスタ (UJT) プログラマブル・ユニジャンクション・トランジスタ（英語版） (PUT) 静電誘導トランジスタ (SIT) テトロードトランジスタ（英語版） ダイオード アバランシェダイオード en:Constant-current diode (CLD, CRD) レーザーダイオード (LD) 発光ダイオード (LED) 有機エレクトロルミネッセンス (OLED) フォトダイオード PINダイオード ショットキーバリアダイオード ステップリカバリダイオード（英語版） ツェナーダイオード ガン・ダイオード 他のデバイス DIAC en:Heterostructure barrier varactor 集積回路 (IC) en:Memistor Memory cell メモリスタ en:Mixed-signal integrated circuit en:MOS integrated circuit (MOS IC) 有機半導体 光検出器 en:RF CMOS en:Solaristor 量子回路 en:Silicon controlled rectifier (SCR) 静電誘導サイリスタ (SITh) en:Three-dimensional integrated circuit (3D IC) サイリスタ en:TRIAC バリキャップ
電圧調整器（英語版）	リニアレギュレータ 低損失レギュレータ en:Switching regulator Buck Boost Buck–boost Split-pi Ćuk SEPIC チャージポンプ スイッチトキャパシタ
真空管	en:Acorn tube オーディオン管 en:Beam tetrode Barretter コンパクトロン Diode en:Fleming valve en:Nonode en:Nuvistor Pentagrid (Hexode, Heptode, Octode) 光電子増倍管 光電管 三極真空管 四極真空管 五極真空管
真空管 (RF)	en:Backward-wave oscillator (BWO) マグネトロン en:Crossed-field amplifier (CFA) ジャイロトロン en:Inductive output tube (IOT) クライストロン メーザー サットン管（英語版） 進行波管 (TWT)
陰極線管	en:Beam deflection tube en:Charactron en:Iconoscope マジックアイ en:Monoscope セレクトロン管 蓄積管 ニキシー管 撮像管 ウィリアムス管
ガス封入管	冷陰極管 en:Crossatron 計数放電管 en:Ignitron en:Krytron 水銀整流器 ネオン管 ニキシー管 サイラトロン en:Trigatron en:Voltage-regulator tube
可変	ポテンショメータ digital エアバリコン バリキャップ
受動	コネクタ AV端子 電源 RF en:Electrolytic detector フェライト ヒューズ resettable 抵抗器 開閉器 サーミスタ 変圧器 バリスタ 針金 en:Wollaston wire
リアクタンス	コンデンサ types セラミック発振子 水晶振動子 インダクタ パラメトロン 継電器 en:reed relay 水銀スイッチ
カテゴリ

参考文献[編集]

• "The rhumbatron wave-guide switch" Journal of the Institution of Electrical Engineers - Part IIIA: Radiolocation, Volume 93 Issue 4 (1946), pp. 700–702
• A.L. Samuel, J.W. Clark and W.W. Mumford, "The Gas-Discharge Transmit-Receive Switch", Bell System Technical Journal, 1946, pp. 48–101.

外部リンク[編集]

• NR89 Sutton Tube, a local oscillator
• CV43, a Sutton switch
• Sutton tube - Radiomuseum.org
• The Sutton tube, the first reflex klystron oscillator - A.S.E. – Associazione Storia dell’Elettronica

[[Category:真空管]] [[Category:マイクロ波]] [[Category:未査読の翻訳があるページ]]

1. ^ A. MacLese & J. Ashmead (1946). “The rhumbatron wave-guide switch”. Journal of the Institution of Electrical Engineers - Part IIIA: Radiolocation Volume 93, Issue 4: 700 – 702. 
2. ^ Caryotakis 1998, p. 3.
3. ^ ^{a b} Caryotakis 1998, pp. 1–2.
4. ^ ^{a b c d} Watson 2009, p. 146.
5. ^ ^{a b c} Lovell 1991, p. 61.
6. ^ Lovell 1991, p. 62.
7. ^ ^{a b c} Hodgkin 1994, p. 192.
8. ^ ^{a b c d} Lovell 1991, p. 63.
9. ^ Watson 2009, p. 165.