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2018-11-01

スマッシュブラザーズ、新キャラPVの「参戦!」英語まとめ

スマッシュブラザーズ新規キャラクター参戦が発表されるたびにYoutubeリアクション動画投稿されて話題になっていますね!

自分もそのての動画を見て楽しんでいたのですが、リドリー参戦を見た時に気になったことがありました。

Ridley Hits the Big Time!

あれ?日本語ではすべて「リドリー参戦!」といった具合に「~参戦!」で統一されているけど、英語版はそれぞれ違っていてバリエーションがあるのかな?  …と

調べてもこれをまとめたのが見つからなかったので、まとめてみました。

キャラクター名(日本語キャラクター名(英語参戦!の英語表記語句語句意味意味言葉遊び?要素(推測)
むらびとVillagerVillager Comes to Town!---
ロックマンMega ManMega Man Joins the Battle!---
Wii Fit トレーナWii Fit TrainerWii Fit Trainer Weighs In!weigh in計量する、割って入る、仲裁に入る計量する→体重測定?
ロゼッタチコRosalina & LumaRosalina & Luma launch into battle!launch into始める、門出するLaunch:(ロケットなどを)打ち上げる→ほうき星天文台
リトルマックLittle MacLittle Mac Punches In!punch in打ち込むボクサー
リザードンCharizardCharizard Fires it Up!fire up火をつける、始動させる、駆り立てるほのおタイプポケモン
ゲッコウガGreninjaGreninja Makes A Splash!make a splash音を立てる、あっと言わせる、水しぶきを上げるみずタイプポケモン
パルテナPalutenaPalutena Alights!alight降りる(天から)降りる?
パックマンPac-ManPac-Man Hungers for Battle!hunger for切望するHunger←ゲーム性から
ルキナLucinaLucina Wakes Her Blade?!--ファイアーエンブレム 覚醒(Awakening)とかけてる?
ルフレRobinRobin Brings the Thunder!--サンダーソードという武器を使う
シュルクShulkShulk Foresees a Fight!foresee見越す、予見する未来視という能力がある
クッパJr.Bowser Jr.Bowser Jr. Clowns the Competition!clownふざけるいたずら
ダックハントDuck HuntDuck Hunt Takes Aim!take aim狙いを定めるカモを狙い撃つゲーム性から
ミュウツーMewtwoMewtwo Strikes Back!strike back殴り返す、反撃するミュウツーの逆襲
リュカLucasLucas Comes Out of Nowhere!come out of nowhere突然やってくるリュカはノーウェア(Nowhere)島に住んでいる
ロイRoyRoy Seals the Deal!seal the deal契約を結ぶ、取引を固めるロイ封印(seal)の剣の主人公
リュウRyuHere Comes A New Challenger! Ryu--ストリートファイター乱入時のメッセージ
クラウドCloudCloud Storms into Battle!storm into押し入る、突入するStorm Clouds(凶兆、悪いことが起こる前兆
カムイCorrinCorrin Chooses to Smash!choose to do決めるファイアーエンブレムifの「運命分岐点」で選択肢を選ぶから
ベヨネッタBayonettaBayonetta Gets Wicked!---
リドリーRidleyRidley Hits the Big Time!hit the big time成功する、一流になる、大当たりするRidley is too big.というネットミーム
シモンSimonSimon Lashes Out!lash out暴力攻撃する、食って掛かるLash(ムチ)→メインウェポンがムチ
リヒターRichterRichter Crosses Over!cross overクロスオーバーする、枠を超えるCross→横必殺技クロス十字架ブーメラン
クロムChromChrom Joins the Battle!---
ダークサムスDark SamusDark Samus Joins the Battle!---
キングクルールKing K. RoolKing K. Rool Comes Aboard!come aboard(船に)乗り込む、参加する船に乗り込む→キャプテン
しずえIsabelleIsabelle Turns Over A New Leaf!turn over a new leaf改心する、心機一転するとびだせ どうぶつの森」の英語タイトルが「Animal Crossing: New Leaf
ケンKenKen Turns Up the Heat!turn up the heat温度をあげる、強火にする、勢いを増すケンリュウと違い、昇龍拳で火を噴く
ガオガエンIncineroarIncineroar Enters the Ring!enter the ringリングに入るプロレス技を使うキャラクターなので
パックンフラワーPiranha PlantPiranha Plant Pipes Up!pipe upしゃべり(歌い)始める、甲高い声で話す、汲み上げる土管
バンジョーカズーBanjo-KazooieBanjo-Kazooie are Raring to Go!raring to go今か今かと待ち切れない、~したくてしかたがない開発元がRare社
勇者HeroThe Hero Draws Near!draw nearそこに向かって動く

備考)ベヨネッタの「Get Wicked」は調べてもヒットせず、いまいちわかりませんでした。Wickedは「邪悪な、いたずらな」という意味

こうしてみるとキャラの特徴をとらえた言葉選びがあって面白いですね!

調べてたら発見した関連ページ

http://smashbrossp.net/archives/8777

https://smashbrosmatome.work/2018/09/17/post-3706/

http://smashwiki.info/%E3%82%B9%E3%83%9E%E3%83%96%E3%83%A9SP%E3%81%AE%E5%8F%82%E6%88%A6%E3%83%A0%E3%83%BC%E3%83%93%E3%83%BC%E3%83%BB%E3%83%97%E3%83%AD%E3%83%83%E3%83%88%E9%9B%86

追記

遊んだことな元ネタゲームが多く言葉遊び要素が分からなくて探すのに苦労しました。コメントでご指摘いただいた部分は修正してます

あと自分はどっかまとまった情報が見たかっただけなので、誰かこの情報をどこかのサイトにまとめ直してくれてもいいです。

2018-03-11

asagiri-kogen.camp

http://asagiri-kogen.camp/

Hello! So, this page got a lot more hits than I ever thought it would. I created this as a tribute to my favourite anime of the season, and as a little easter egg for fellow Yuru Camp fans to find. I hope you enjoy it!

皆さん、こんばんは。 下手な日本語すみませんGoogle翻訳を使っています。私はあなたにこれを見つけることをお祝いします。 このウェブサイトヨーロッパファンによって作成されました。 URL使用されていないことがわかったとき、私は他のファンのために驚きを作りたがっていました。 私はこのページを見つけることがあなたにとってすばらしい驚きであったことを願っています私たちはるかに離れていますが、私たちは同じアニメーションを楽しんで少しずつお互いを理解できると思います。今はヨーロッパでは非常に寒いですが、女の子キャンプを楽しんでいるのを見たら、少し暖かく感じます。同じように感じますか? 世界中の愛されているアニメーションを作ってくれてありがとう

camp ドメインなんてあるのね。

2017-10-01

Russian military hits terrorist positions in Idlib, denies strikes on civilians

https://youtu.be/Yn_npU4mNVk?t=47

人体の数倍でかい精度の低い弾丸落としといてよく民間人に死者はいませんでしたなんてどの口が言うんだよ脳みそ花畑

2017-05-05

http://anond.hatelabo.jp/20170505124802

何がメジャーで何がマイナーかは判別難しいから何とも言えない

最近同人CD普通にレンタル屋に置いてあるから

あと考えられるのはVAものHITSとかそういうの)を入れたら

文字化け設定のデータ登録されてるせいで通信エラーが出て

PCならYES/NO選べば解消される問題コケっぱなしって可能性だろうね

んで数か月後にそのデータ登録されてるから無事通るとか

ただ、その場合は読み込むCDの順番を入れ替えたらうまく行くはずだから

エラーメッセージ出しっぱなしになってる車載プログラム問題なんじゃなかろうか

カーナビ会社に問い合わせたほうが話早いのかも

 

 

トヨタカーナビ調べてみたら、年会費パケット使い放題らしいんだけど

元増田はまとめてCD登録するってことで

実際には存在する月当たりのパケット量上限に行っちゃってる可能性ない?

パケの縛りが終わったら普通に通信できるようになるとか…

 

  

しかし同種のエラーが多いようなら、さすがにサポセンでも問題視して対応するだろうから

無視できるレベルしか出てないエラーなんだと思うよ

2016-03-20

10 Tips for Last Hitting - Dota 2

http://www.tentonhammer.com/guides/dota-2/10-tips-last-hitting-dota-2

Know Your Creeps -

クリープについて理解しろ

Melee creeps have more health than caster creeps

Melee系のクリープは、Ranged系より体力が多い

so you may have to wait a little longer before going for the last hit.

そのため、ラストヒットを取るタイミングは、若干遅らせなければならない場合がある

Another thing to pay attention to,

もう一つ気をつけるべきことは、

is how much damage the creeps do to one another.

Melee系とRanged系が互いに与えるダメージである

フィールド上の敵、味方クリープが)お互いに与えるダメージである

Once you've got a feel for that,

これを意識できるようになると、

you should be able to tell how many hits from a melee/ ranged creep

melee系またはranged系クリープから何発の攻撃を受けるか予測できるはずである

it will take to get an enemy creep into the "sweet spot".

これにより、最適なラストヒットのタイミングを把握できる

※各種クリープの体力値

http://dota2.gamepedia.com/Creeps

Melee creep 550 (+10)

Ranged creep 300 (+10)

Siege creep 550

Melee系はRanged系の2倍近い体力がある。

また、Melee系とSiege creepの体力はほぼ同じである

Siege creepは、Armorが0であることにも注目。

2011-03-14

福島原子力発電所CNNコメント欄 MIT科学者科学者見解1【東日本巨大地震

結論:大丈夫

MvK2010

I'm going to copy paste a full blog post of a research scientist at MIT here, who explains the situation at Fukushima much better than anyone else has, his message: no worries.

This post is by Dr Josef Oehmen, a research scientist at MIT, in Boston.

He is a PhD Scientist, whose father has extensive experience in Germany’s nuclear industry. I asked him to write this information to my family in Australia, who were being made sick with worry by the media reports coming from Japan. I am republishing it with his permission.

It is a few hours old, so if any information is out of date, blame me for the delay in getting it published.

This is his text in full and unedited. It is very long, so get comfy.

I am writing this text (Mar 12) to give you some peace of mind regarding some of the troubles in Japan, that is the safety of Japan’s nuclear reactors. Up front, the situation is serious, but under control. And this text is long! But you will know more about nuclear power plants after reading it than all journalists on this planet put together.

There was and will *not* be any significant release of radioactivity.

By “significant” I mean a level of radiation of more than what you would receive on – say – a long distance flight, or drinking a glass of beer that comes from certain areas with high levels of natural background radiation.

I have been reading every news release on the incident since the earthquake. There has not been one single (!) report that was accurate and free of errors (and part of that problem is also a weakness in the Japanese crisis communication). By “not free of errors” I do not refer to tendentious anti-nuclear journalism – that is quite normal these days. By “not free of errors” I mean blatant errors regarding physics and natural law, as well as gross misinterpretation of facts, due to an obvious lack of fundamental and basic understanding of the way nuclear reactors are build and operated. I have read a 3 page report on CNN where every single paragraph contained an error.

We will have to cover some fundamentals, before we get into what is going on.

Construction of the Fukushima nuclear power plants

The plants at Fukushima are so called Boiling Water Reactors, or BWR for short. Boiling Water Reactors are similar to a pressure cooker. The nuclear fuel heats water, the water boils and creates steam, the steam then drives turbines that create the electricity, and the steam is then cooled and condensed back to water, and the water send back to be heated by the nuclear fuel. The pressure cooker operates at about 250 °C.

The nuclear fuel is uranium oxide. Uranium oxide is a ceramic with a very high melting point of about 3000 °C. The fuel is manufactured in pellets (think little cylinders the size of Lego bricks). Those pieces are then put into a long tube made of Zircaloy with a melting point of 2200 °C, and sealed tight. The assembly is called a fuel rod. These fuel rods are then put together to form larger packages, and a number of these packages are then put into the reactor. All these packages together are referred to as “the core”.

The Zircaloy casing is the first containment. It separates the radioactive fuel from the rest of the world.

The core is then placed in the “pressure vessels”. That is the pressure cooker we talked about before. The pressure vessels is the second containment. This is one sturdy piece of a pot, designed to safely contain the core for temperatures several hundred °C. That covers the scenarios where cooling can be restored at some point.

The entire “hardware” of the nuclear reactor – the pressure vessel and all pipes, pumps, coolant (water) reserves, are then encased in the third containment. The third containment is a hermetically (air tight) sealed, very thick bubble of the strongest steel. The third containment is designed, built and tested for one single purpose: To contain, indefinitely, a complete core meltdown. For that purpose, a large and thick concrete basin is cast under the pressure vessel (the second containment), which is filled with graphite, all inside the third containment. This is the so-called “core catcher”. If the core melts and the pressure vessel bursts (and eventually melts), it will catch the molten fuel and everything else. It is built in such a way that the nuclear fuel will be spread out, so it can cool down.

This third containment is then surrounded by the reactor building. The reactor building is an outer shell that is supposed to keep the weather out, but nothing in. (this is the part that was damaged in the explosion, but more to that later).

Fundamentals of nuclear reactions

The uranium fuel generates heat by nuclear fission. Big uranium atoms are split into smaller atoms. That generates heat plus neutrons (one of the particles that forms an atom). When the neutron hits another uranium atom, that splits, generating more neutrons and so on. That is called the nuclear chain reaction.

Now, just packing a lot of fuel rods next to each other would quickly lead to overheating and after about 45 minutes to a melting of the fuel rods. It is worth mentioning at this point that the nuclear fuel in a reactor can *never* cause a nuclear explosion the type of a nuclear bomb. Building a nuclear bomb is actually quite difficult (ask Iran). In Chernobyl, the explosion was caused by excessive pressure buildup, hydrogen explosion and rupture of all containments, propelling molten core material into the environment (a “dirty bomb”). Why that did not and will not happen in Japan, further below.

In order to control the nuclear chain reaction, the reactor operators use so-called “moderator rods”. The moderator rods absorb the neutrons and kill the chain reaction instantaneously. A nuclear reactor is built in such a way, that when operating normally, you take out all the moderator rods. The coolant water then takes away the heat (and converts it into steam and electricity) at the same rate as the core produces it. And you have a lot of leeway around the standard operating point of 250°C.

The challenge is that after inserting the rods and stopping the chain reaction, the core still keeps producing heat. The uranium “stopped” the chain reaction. But a number of intermediate radioactive elements are created by the uranium during its fission process, most notably Cesium and Iodine isotopes, i.e. radioactive versions of these elements that will eventually split up into smaller atoms and not be radioactive anymore. Those elements keep decaying and producing heat. Because they are not regenerated any longer from the uranium (the uranium stopped decaying after the moderator rods were put in), they get less and less, and so the core cools down over a matter of days, until those intermediate radioactive elements are used up.

This residual heat is causing the headaches right now.

So the first “type” of radioactive material is the uranium in the fuel rods, plus the intermediate radioactive elements that the uranium splits into, also inside the fuel rod (Cesium and Iodine).

There is a second type of radioactive material created, outside the fuel rods. The big main difference up front: Those radioactive materials have a very short half-life, that means that they decay very fast and split into non-radioactive materials. By fast I mean seconds. So if these radioactive materials are released into the environment, yes, radioactivity was released, but no, it is not dangerous, at all. Why? By the time you spelled “R-A-D-I-O-N-U-C-L-I-D-E”, they will be harmless, because they will have split up into non radioactive elements. Those radioactive elements are N-16, the radioactive isotope (or version) of nitrogen (air). The others are noble gases such as Xenon. But where do they come from? When the uranium splits, it generates a neutron (see above). Most of these neutrons will hit other uranium atoms and keep the nuclear chain reaction going. But some will leave the fuel rod and hit the water molecules, or the air that is in the water. Then, a non-radioactive element can “capture” the neutron. It becomes radioactive. As described above, it will quickly (seconds) get rid again of the neutron to return to its former beautiful self.

This second “type” of radiation is very important when we talk about the radioactivity being released into the environment later on.

What happened at Fukushima

I will try to summarize the main facts. The earthquake that hit Japan was 7 times more powerful than the worst earthquake the nuclear power plant was built for (the Richter scale works logarithmically; the difference between the 8.2 that the plants were built for and the 8.9 that happened is 7 times, not 0.7). So the first hooray for Japanese engineering, everything held up.

When the earthquake hit with 8.9, the nuclear reactors all went into automatic shutdown. Within seconds after the earthquake started, the moderator rods had been inserted into the core and nuclear chain reaction of the uranium stopped. Now, the cooling system has to carry away the residual heat. The residual heat load is about 3% of the heat load under normal operating conditions.

The earthquake destroyed the external power supply of the nuclear reactor. That is one of the most serious accidents for a nuclear power plant, and accordingly, a “plant black out” receives a lot of attention when designing backup systems. The power is needed to keep the coolant pumps working. Since the power plant had been shut down, it cannot produce any electricity by itself any more.

Things were going well for an hour. One set of multiple sets of emergency Diesel power generators kicked in and provided the electricity that was needed. Then the Tsunami came, much bigger than people had expected when building the power plant (see above, factor 7). The tsunami took out all multiple sets of backup Diesel generators.

When designing a nuclear power plant, engineers follow a philosophy called “Defense of Depth”. That means that you first build everything to withstand the worst catastrophe you can imagine, and then design the plant in such a way that it can still handle one system failure (that you thought could never happen) after the other. A tsunami taking out all backup power in one swift strike is such a scenario. The last line of defense is putting everything into the third containment (see above), that will keep everything, whatever the mess, moderator rods in our out, core molten or not, inside the reactor.

http://anond.hatelabo.jp/20110314030613

へ続く

2009-11-25

http://anond.hatelabo.jp/20091125133959

アメリカは既に金融が半死にしてるから、円高に進むんだよw

FEDB/S見ると、その単位めまいがするw


Fed Balance Sheet Hits Record $2.2 Trillion In Assets On $71 Billion Weekly Increase In MBS

http://www.zerohedge.com/article/fed-balance-sheet-hits-record-22-trillion-assets-71-billion-increase-mbs

 
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