 | Perfect Passwords GRC's Ultra High Security Password Generator | |
| 1,798 sets of passwords generated per day 37,645,721 sets of passwords generated for our visitors | ||
  not simple. So here is some totally random raw material, generated just for YOU, to start with. Every time this page is displayed, our server generates a unique set of custom, high quality, cryptographic-strength password strings which are safe for you to use: |
64 random hexadecimal characters (0-9 and A-F):
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63 random printable ASCII characters:
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63 random alpha-numeric characters (a-z, A-Z, 0-9):
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| Click your web browser's "refresh" button a few times and watch the password strings change each time.
What makes these perfect and safe? Also, because this page will only allow itself to be displayed over a snoop-proof and proxy-proof high-security SSL connection, and it is marked as having expired back in 1999, this page which was custom generated just now for you will not be cached or visible to anyone else. Therefore, these password strings are just for you. No one else can ever see them or get them. You may safely take these strings as they are, or use chunks from several to build your own if you prefer, or do whatever you want with them. Each set displayed are totally, uniquely yours — forever. The "Application Notes" section below discusses various aspects of using these random passwords for locking down wireless WEP and WPA networks, for use as VPN shared secrets, as well as for other purposes. The "Techie Details" section at the end describes exactly how these super-strong maximum-entropy passwords are generated (to satisfy the uber-geek inside you). |
Application Notes:
A note about "random" and "pseudo-random" terminology: There are ways to generate absolutely random numbers, but computer algorithms cannot be used for that, since, by definition, no deterministic mathematical algorithm can generate a random result. Electrical and mechanical noise found in chaotic physical systems can be tapped and used as a source of true randomness, but this is much more than is needed for our purposes here. High quality algorithms are sufficient. The deterministic binary noise generated by my server, which is then converted into various displayable formats, is derived from the highest quality mathematical pseudo-random algorithms known. In other words, these password strings are as random as anything non-random can be.
This page's password "raw material":
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64 hex characters = 256 binary bits:
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| Each of the 64 hexadecimal characters encodes 4 bits of binary data, so the entire 64 characters is equivalent to 256 binary bits — which is the actual binary key length used by the WiFi WPA pre-shared key (PSK). Some WPA-PSK user interfaces (such as the one in Windows XP) allows the 256-bit WPA pre-shared key to be directly provided as 64 hexadecimal characters. This is a precise means for supplying the WPA keying material, but it is ONLY useful if ALL of the devices in a WPA-protected WiFi network allow the 256-bit keying material to be specified as raw hex. If any device did not support this mode of specification (and most do not) it would not be able to join the network.
Using fewer hex characters for WEP encryption: WEP key strength (key length) is sometimes confusing because, although there are only two widely accepted standard lengths, 40-bit and 104-bit, those lengths are sometimes confused by adding the 24-bit IV (initialization vector) counter to the length, resulting in 64-bit and 128-bit total key lengths. However, the user only ever specifies a key of either 40 or 104 binary bits. Since WEP keys should always be specified in their hexadecimal form to guarantee device interaction, and since each hex digit represents 4 binary bits of the key, 40 and 104 bit keys are represented by 10 and 26 hex digits respectively. So you may simply snip off whatever length of random hex characters you require for your system's WEP key. Note that if all of your equipment supports the use of the new longer 256/232 bit WEP keys, you would use 232/4 or 58 hexadecimal characters for your pre-shared key.
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| The more "standard" means for specifying the 256-bits of WPA keying material is for the user to specify a string of up to 63 printable ASCII characters. This string is then "hashed" along with the network's SSID designation to form a cryptographically strong 256-bit result which is then used by all devices within the WPA-secured WiFi network. (The ASCII character set was updated to remove SPACE characters since a number of WPA devices were not handling spaces as they should.)
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| If some device was not following the WiFi Alliance WPA specification by not hashing the entire printable ASCII character set correctly, it would end up with a different 256-bit hash result than devices that correctly obeyed the specification. It would then be unable to connect to any network that uses the full range of printable ASCII characters.
Since we have heard unconfirmed anecdotal reports of such non-compliant WPA devices (and since you might have one), this page also offers "junior" WPA password strings using only the "easy" ASCII characters which even any non-fully-specification-compliant device would have to be able to properly handle. If you find that using the full random ASCII character set within your WPA-PSK protected WiFi network causes one of your devices to be unable to connect to your WPA protected access point, you can downgrade your WPA network to "easy ASCII" by using one of these easy keys. And don't worry for a moment about using an easy ASCII key. If you still use a full-length 63 character key, your entire network will still be EXTREMELY secure. And PLEASE drop us a line to let us know that you have such a device and what it is!
When these passwords are used to generate pre-shared keys for protecting WPA WiFi and VPN networks, the only known attack is the use of "brute force" — trying every possible password combination. Brute force attackers hope that the network's designer (you) were lazy and used a shorter password for "convenience". So they start by trying all one-character passwords, then two-character, then three and so on, working their way up toward longer random passwords.
Note that while this "the longer the better" rule of thumb is always true, long passwords won't protect legacy WEP-protected networks due to well known and readily exploited weaknesses in the WEP keying system and its misuse of WEP's RC4 encryption. With WEP protection, even a highly random maximum-entropy key can be cracked in a few hours. (Listen to Security Now! episode #11 for the full story on cracking WEP security.)
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While the diagram above might at first seem a bit confusing, it is a common and well understood configuration of standard cryptographic elements. A succinct written description of the algorithm would read: "Rijndael (AES) block encryption of never-repeating counter values in CBC mode." CBC stands for "Cipher Block Chaining" and, as I describe in detail in the second half of Security Now! Episode #107, CBC provides necessary security in situations where some repetition or predictability of the "plaintext" message is present. Since the "plaintext" in this instance is a large 128-bit steadily-increasing (monotonic) counter value (which gives us our guaranteed never-to-repeat property, but is also extremely predictable) we need to scramble it so that the value being encrypted cannot be predicted. This is what "CBC" does: As the diagram above shows, the output from the previous encryption operation is "fed back" and XOR-mixed with the incrementing counter value. This prevents the possibility of determining the secret key by analysing successive counter encryption results. One last detail: Since there is no "output from the previous encryption" to be used during the encryption of the first block, the switch shown in the diagram above is used to supply a 128-bit "Initialization Vector" (which is just 128-bits of secret random data) for the XOR-mixing of the first counter value. Thus, the first encryption is performed on a mixture of the 128-bit counter and the "Initialization Vector" value, and subsequent encryptions are performed on the mixture of the incrementing counter and the previous encrypted result. The result of the combination of the 256-bit Rijndael/AES secret key, the unknowable (therefore secret) present value of the 128-bit monotonically incrementing counter, and the 128-bit secret Initialization Vector (IV) is 512-bits of secret data providing extremely high security for the generation of this page's "perfect passwords". No one is going to figure out what passwords you have just received. How much security do 512 binary bits provide? Well, 2^512 (2 raised to the power of 512) is the total number of possible combinations of those 512 binary bits — every single bit of which actively participates in determining this page's successive password sequence. 2^512 is approximately equal to: 1.34078079 x 10^154, which is this rather amazing number:
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 | Convert Studio3 To Pdf FileAnd yet, this conversion is one of the most profound acts a creator can perform. Because a PDF is not a lesser thing—it is a different thing. It is the difference between the experience of making and the architecture of that experience. Windows 10 and 11 have a built-in virtual printer that makes this process seamless. Open your .studio3 file in Silhouette Studio. Go to > Print (or press Ctrl + P ). This is the most reliable method, as it uses the official software designed to work with your file. If you use Silhouette Studio for commercial purposes, upgrading to the is highly recommended. The Basic (free) and Designer editions do not allow direct PDF exporting, but the Business Edition unlocks this native feature. In conclusion, converting a Studio3 file to PDF is a fundamental workflow step that transitions a creative project into a distributable document. Whether through an automated export of track lists and metadata or through the manual capture of the mixing console interface, convert studio3 to pdf There are two primary methods to achieve this: So convert your session to PDF. Print it. Frame it if you must. Because one day, the software will be obsolete, the plugins will be abandonware, the operating system will be a forgotten footnote. But that PDF—that flat, silent, rectangular ghost—will still speak. Not in frequencies, but in forms . Not in decibels, but in decisions . To convert a file (the proprietary format for Silhouette Studio ) to a PDF, you can either use the software's built-in export features or a "virtual printer" workaround depending on your software edition. Method 1: Using Silhouette Studio Business Edition In the printer selection window, select . Click Print . And yet, this conversion is one of the If none of these methods work, please provide: If you own the Business Edition of Silhouette Studio, the software allows you to export files directly to PDF. This is the most efficient and accurate method available. Step-by-Step Instructions But here lies the deeper truth. In a world of collaborative creation, of client revisions, of legal ownership disputes and educational breakdowns, the Studio3 file is a locked room. Only those with the specific key (the software, the version, the plugins, the sample libraries) can enter. The PDF is the universal translator. It is the Rosetta Stone of creative intention. If you do not have Silhouette Studio installed, you may need to use a third-party converter, though these are less reliable for retaining cut-line accuracy. Windows 10 and 11 have a built-in virtual If this is for a project with registration marks? Goal: Share a project’s content as documentation or a printable mix sheet, or export audio to a PDF-friendly format such as waveform images or annotated stems list. In the bottom-left corner of the print dialog box, click the small dropdown menu labeled PDF . Click on in the top menu bar, hover over Save As , and select Save to Hard Drive . Step 3: Select PDF Format |  |