はてなキーワード: the plugとは
VitaにCFWを導入するにあたり、情報が散乱していたのでまとめる
・2022年末に革新的進歩があり、VITA単体でCFW導入できるようになった(通称 HENlo)
・にも関わらず古いCFW導入方法を案内しているブログが大量にある
・しかもタイトルの"20XX年最新"だけ更新し続けているから、最新記事に見える
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PC使用が前提になっているブログは全部古いので無視した方が良いです。
・『HENlo』について触れている
この2つが押さえられてれば最新情報です。(2025年5月現在)
ただし、現状だと実は『PC操作が一部必要』という罠があります。
その問題について書いている記事が見当たらないので、ここに残しておきます。
超具体的には
「HENkaku、VitaDeploy、VitaShellは導入できた」
「けどEnso導入ができない/つまづいている」 エラー:failed to get fw version please disable all the plugins and try again
5chでもRedditでも
『プラグインを無効にしろ』『0syscall6を無効にしろ』って書いてあったのですが、実はEnsoのバージョン変えれば解決します。(後述)
この記事が役に立ちました
[Vita] 2023年最新手順【HENlo】3.65-3.74 PC不要でCFW(HENkaku)導入
https://re-doing.com/vita-henlo-hack/
(一応魚拓:https://web.archive.org/web/20250226111105/https://re-doing.com/vita-henlo-hack/)
・HENkaku (カスタムファームウェア 3.65 変革 -2)
・VitaDeploy
・VitaShell
・最悪文鎮化する可能性があるのでセーブデータバックアップを取ったほうが良い
・VITAのセーブデータは特殊で、PCと繋ぐだけでは取り出せない
・バックアップにはいくつか方法があるが、PCのコンテンツ管理アシスタントは既に使えないと思ったほうが良い。PS Plusのクラウドバックアップが最も良いはず
・記事の内容を実施する前にバックアップ取るのを強くおすすめする
これをインストールすることで、電源を切ってからもCFW状態を維持できます。
VitaDeploy内のApp downloaderメニューからEnsoをインストールできますが、実はこのバージョンが古いです。※重要※
そのためVitaDeployからインストールすると先程のエラー(failed to get fw version please disable all the plugins and try again)が必ず出ます。
「PC不要になった」と書いてあったので盲点ですが、ここからPC必要です。
正しい方法は以下です
1, PC操作:GithubからEnso最新版のenso.vpkファイルをダウンロード(現在v1.1)
https://github.com/TheOfficialFloW/enso/releases
2, PCとVitaをUSBケーブルで繋げる ※データ転送対応ケーブルを使うこと。相性もある
5, PC操作:USBドライブとしてVITAのデータが表示されるので、ダウンロードしていたenso.vpkファイルを置く(フォルダはどこでもOK。自分はルート直下に置きました)
7, Vita操作:VitaShellでenso.vpkを見つける(さっきルートに置いたなら恐らくux0:にある)
9. Vita操作:Do you want to install this package? → ◯ボタン
10. Vita操作:~~~ Would you like to continue the install? ※意訳:「失敗したら文鎮化するけど自己責任だけど続ける?」 → ◯ボタン
11. 進行バーが消えたらインストール完了 ホーム画面に戻ってOK
Ensoはファームウェアが3.60か3.65じゃないとインストールできないです。(3.65 変革 -2は3.65扱い)
先程の記事の通り進めていたら3.65 変革 -2 になっているはずですが、実行前に再確認して下さい。
1, ~~~ Press CIRCLE to accept these terms or any other key to not accept. → ◯ボタンを押す(=CIRCLE )
2, Options:
CROSS Install /reinstall the hack.
SQUARE Fix boot configuration (choose this if taiHEN isn't loading on boot).
CIRCLE Exit without doing anything.
Locking sustem ..
(中略)
The installation was completed successfully.
suocess.
MBR was detected but instllation checksum dose not match.
A dump was created at ux0:data/blocks.bin.
Press X to continue, any othe key to exit.
意訳:「ちょい待った。思ってた構成じゃないから危ないかもしれんわ。続ける?」
→✕ボタンを押す ※結局原因分かってないので自己責任でお願いします※
4, Locking sustem ..
(中略)
The installation was completed successfully.
suocess.
Enso導入が成功していると
・ファームウェアが3.65 変革 -2のままなっている
お疲れ様でした。
記事の本題は以上です。
VITAのセーブデータは暗号化されており、吸い出せてもエミュレータで使えないらしい。本体機体とセットで揃わないと使えない仕様。
調べたらセーブデータをここまでキツく縛ってるハードは他にない
だからメモリーカードのデータ管理でもPSPのセーブデータしか項目がなかったのか…
不便すぎる
当時の仮説
・HENkaku設定が悪さをしているのではないか(PSNの偽装を有効化、バージョンの偽装を有効化) →オフにしたが関係なかった
・本体にSD2VITAを刺しているのが良くないのではないか →抜いたが関係なかった
・enso.vpkの置き場所がルート(ux0:)が良くなかったのではないか →関係なかった
・VITAにメモリーカードを刺しているのが良くないのではないか →関係なかったが、データ保護的には抜くのが良さそう
・ゴミデータが残っていて悪さしているのではないか(手順を間違えたデータや古いデータなど) →関係ある可能性はある。最後までわからず
・Ensoのバージョンが古いのではないか →これが主要因だった
ゴミデータを疑った自分は正規のファームウェアに戻して、CFW化をやり直したりもした。
その際HENkakuすら入れられなくなってしまったので、抜け方を書いておく。
ENSO実行
↓
~~~ Press CIRCLE to accept these terms or any other key to not accept. → ◯ボタンを押す(=CIRCLE )
↓
Options:
CROSS Install /reinstall the hack.
SQUARE Fix boot configuration (choose this if taiHEN isn't loading on boot).
CIRCLE Exit without doing anything.
→ △ボタンを押す(=TRIANGLE Uninstall the hack.)
↓
↓
↓
ファームウェアアップデートが促され、アップデートしないとメモリースティックが使えない
↓
↓
↓
HENloメニュー
・Exit
↓
「Eiting in 3」 の後に、以下のエラーメッセージがでて固まってしまう
vita starting taihen framework
If you are stuck on this screen, hold down the power button until your Vita turns off, then turn it back on.
原因:恐らく余計なデータと衝突を起こしてる
解決法:reset taitan configを先に実行する
(さっきのエラーメッセージ画面で)
↓
セーフモードが起動する
↓
↓
↓
HENloメニュー
・Exit
↓
その後
Install HENkaku、Install VitaDeployを選択して、Exitを選択
この記事を書き終えた後に見つけたのですが、以下の記事の『改造方法』というところに情報がかなりまとまっています
Vita バージョンが低くてもPSNにサインイン&PSストアにアクセス(エラーNW-8942-3回避)&機器認証する方法(2025最新)
https://yyoossk.blogspot.com/2024/10/vitapsnps2024.html
今回VITAのセーブデータバックアップが主目的だったから、徒労でしかなかった
指摘、補足、最新情報あれば反応もらえるとありがたいです
When the diesel generators were gone, the reactor operators switched to emergency battery power. The batteries were designed as one of the backups to the backups, to provide power for cooling the core for 8 hours. And they did.
Within the 8 hours, another power source had to be found and connected to the power plant. The power grid was down due to the earthquake. The diesel generators were destroyed by the tsunami. So mobile diesel generators were trucked in.
This is where things started to go seriously wrong. The external power generators could not be connected to the power plant (the plugs did not fit). So after the batteries ran out, the residual heat could not be carried away any more.
At this point the plant operators begin to follow emergency procedures that are in place for a “loss of cooling event”. It is again a step along the “Depth of Defense” lines. The power to the cooling systems should never have failed completely, but it did, so they “retreat” to the next line of defense. All of this, however shocking it seems to us, is part of the day-to-day training you go through as an operator, right through to managing a core meltdown.
It was at this stage that people started to talk about core meltdown. Because at the end of the day, if cooling cannot be restored, the core will eventually melt (after hours or days), and the last line of defense, the core catcher and third containment, would come into play.
But the goal at this stage was to manage the core while it was heating up, and ensure that the first containment (the Zircaloy tubes that contains the nuclear fuel), as well as the second containment (our pressure cooker) remain intact and operational for as long as possible, to give the engineers time to fix the cooling systems.
Because cooling the core is such a big deal, the reactor has a number of cooling systems, each in multiple versions (the reactor water cleanup system, the decay heat removal, the reactor core isolating cooling, the standby liquid cooling system, and the emergency core cooling system). Which one failed when or did not fail is not clear at this point in time.
So imagine our pressure cooker on the stove, heat on low, but on. The operators use whatever cooling system capacity they have to get rid of as much heat as possible, but the pressure starts building up. The priority now is to maintain integrity of the first containment (keep temperature of the fuel rods below 2200°C), as well as the second containment, the pressure cooker. In order to maintain integrity of the pressure cooker (the second containment), the pressure has to be released from time to time. Because the ability to do that in an emergency is so important, the reactor has 11 pressure release valves. The operators now started venting steam from time to time to control the pressure. The temperature at this stage was about 550°C.
This is when the reports about “radiation leakage” starting coming in. I believe I explained above why venting the steam is theoretically the same as releasing radiation into the environment, but why it was and is not dangerous. The radioactive nitrogen as well as the noble gases do not pose a threat to human health.
At some stage during this venting, the explosion occurred. The explosion took place outside of the third containment (our “last line of defense”), and the reactor building. Remember that the reactor building has no function in keeping the radioactivity contained. It is not entirely clear yet what has happened, but this is the likely scenario: The operators decided to vent the steam from the pressure vessel not directly into the environment, but into the space between the third containment and the reactor building (to give the radioactivity in the steam more time to subside). The problem is that at the high temperatures that the core had reached at this stage, water molecules can “disassociate” into oxygen and hydrogen – an explosive mixture. And it did explode, outside the third containment, damaging the reactor building around. It was that sort of explosion, but inside the pressure vessel (because it was badly designed and not managed properly by the operators) that lead to the explosion of Chernobyl. This was never a risk at Fukushima. The problem of hydrogen-oxygen formation is one of the biggies when you design a power plant (if you are not Soviet, that is), so the reactor is build and operated in a way it cannot happen inside the containment. It happened outside, which was not intended but a possible scenario and OK, because it did not pose a risk for the containment.
So the pressure was under control, as steam was vented. Now, if you keep boiling your pot, the problem is that the water level will keep falling and falling. The core is covered by several meters of water in order to allow for some time to pass (hours, days) before it gets exposed. Once the rods start to be exposed at the top, the exposed parts will reach the critical temperature of 2200 °C after about 45 minutes. This is when the first containment, the Zircaloy tube, would fail.
And this started to happen. The cooling could not be restored before there was some (very limited, but still) damage to the casing of some of the fuel. The nuclear material itself was still intact, but the surrounding Zircaloy shell had started melting. What happened now is that some of the byproducts of the uranium decay – radioactive Cesium and Iodine – started to mix with the steam. The big problem, uranium, was still under control, because the uranium oxide rods were good until 3000 °C. It is confirmed that a very small amount of Cesium and Iodine was measured in the steam that was released into the atmosphere.
It seems this was the “go signal” for a major plan B. The small amounts of Cesium that were measured told the operators that the first containment on one of the rods somewhere was about to give. The Plan A had been to restore one of the regular cooling systems to the core. Why that failed is unclear. One plausible explanation is that the tsunami also took away / polluted all the clean water needed for the regular cooling systems.
The water used in the cooling system is very clean, demineralized (like distilled) water. The reason to use pure water is the above mentioned activation by the neutrons from the Uranium: Pure water does not get activated much, so stays practically radioactive-free. Dirt or salt in the water will absorb the neutrons quicker, becoming more radioactive. This has no effect whatsoever on the core – it does not care what it is cooled by. But it makes life more difficult for the operators and mechanics when they have to deal with activated (i.e. slightly radioactive) water.
But Plan A had failed – cooling systems down or additional clean water unavailable – so Plan B came into effect. This is what it looks like happened:
In order to prevent a core meltdown, the operators started to use sea water to cool the core. I am not quite sure if they flooded our pressure cooker with it (the second containment), or if they flooded the third containment, immersing the pressure cooker. But that is not relevant for us.
The point is that the nuclear fuel has now been cooled down. Because the chain reaction has been stopped a long time ago, there is only very little residual heat being produced now. The large amount of cooling water that has been used is sufficient to take up that heat. Because it is a lot of water, the core does not produce sufficient heat any more to produce any significant pressure. Also, boric acid has been added to the seawater. Boric acid is “liquid control rod”. Whatever decay is still going on, the Boron will capture the neutrons and further speed up the cooling down of the core.
The plant came close to a core meltdown. Here is the worst-case scenario that was avoided: If the seawater could not have been used for treatment, the operators would have continued to vent the water steam to avoid pressure buildup. The third containment would then have been completely sealed to allow the core meltdown to happen without releasing radioactive material. After the meltdown, there would have been a waiting period for the intermediate radioactive materials to decay inside the reactor, and all radioactive particles to settle on a surface inside the containment. The cooling system would have been restored eventually, and the molten core cooled to a manageable temperature. The containment would have been cleaned up on the inside. Then a messy job of removing the molten core from the containment would have begun, packing the (now solid again) fuel bit by bit into transportation containers to be shipped to processing plants. Depending on the damage, the block of the plant would then either be repaired or dismantled.
Now, where does that leave us?
・The plant is safe now and will stay safe.
・Japan is looking at an INES Level 4 Accident: Nuclear accident with local consequences. That is bad for the company that owns the plant, but not for anyone else.
・Some radiation was released when the pressure vessel was vented. All radioactive isotopes from the activated steam have gone (decayed). A very small amount of Cesium was released, as well as Iodine. If you were sitting on top of the plants’ chimney when they were venting, you should probably give up smoking to return to your former life expectancy. The Cesium and Iodine isotopes were carried out to the sea and will never be seen again.
・There was some limited damage to the first containment. That means that some amounts of radioactive Cesium and Iodine will also be released into the cooling water, but no Uranium or other nasty stuff (the Uranium oxide does not “dissolve” in the water). There are facilities for treating the cooling water inside the third containment. The radioactive Cesium and Iodine will be removed there and eventually stored as radioactive waste in terminal storage.
・The seawater used as cooling water will be activated to some degree. Because the control rods are fully inserted, the Uranium chain reaction is not happening. That means the “main” nuclear reaction is not happening, thus not contributing to the activation. The intermediate radioactive materials (Cesium and Iodine) are also almost gone at this stage, because the Uranium decay was stopped a long time ago. This further reduces the activation. The bottom line is that there will be some low level of activation of the seawater, which will also be removed by the treatment facilities.
・The seawater will then be replaced over time with the “normal” cooling water
・The reactor core will then be dismantled and transported to a processing facility, just like during a regular fuel change.
・Fuel rods and the entire plant will be checked for potential damage. This will take about 4-5 years.
・The safety systems on all Japanese plants will be upgraded to withstand a 9.0 earthquake and tsunami (or worse)
・I believe the most significant problem will be a prolonged power shortage. About half of Japan’s nuclear reactors will probably have to be inspected, reducing the nation’s power generating capacity by 15%. This will probably be covered by running gas power plants that are usually only used for peak loads to cover some of the base load as well. That will increase your electricity bill, as well as lead to potential power shortages during peak demand, in Japan.
If you want to stay informed, please forget the usual media outlets and consult the following websites:
http://www.world-nuclear-news.org/RS_Battle_to_stabilise_earthquake_reactors_1203111.html
http://bravenewclimate.com/2011/03/12/japan-nuclear-earthquake/
http://ansnuclearcafe.org/2011/03/11/media-updates-on-nuclear-power-stations-in-japan/