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comcast just enabled full ipv6?
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GetawhaleIs it better than when you had v4
yes
[quote=Getawhale]Is it better than when you had v4[/quote]
yes
yes
if anyone can figure out a way to use this as an excuse for missing rockets let me know
if anyone can figure out a way to use this as an excuse for missing rockets let me know
https://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff
https://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff
Raytekhttps://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff
it looks like you get less packet loss
[quote=Raytek]https://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff[/quote]
it looks like you get less packet loss
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff[/quote]
it looks like you get less packet loss
Raytekhttps://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff
fatswimdudeif anyone can figure out a way to use this as an excuse for missing rockets let me know
cmedo u get better ping or what
wont affect network quality, just means we can finally add more devices to the internet and NATs are finally not required
[quote=Raytek]https://superuser.com/questions/181601/is-ipv6-faster-than-ipv4
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff[/quote]
[quote=fatswimdude]if anyone can figure out a way to use this as an excuse for missing rockets let me know[/quote]
[quote=cme]do u get better ping or what[/quote]
wont affect network quality, just means we can finally add more devices to the internet and NATs are finally not required
Seems like you don't really get better latency unless you had bad routing with IPv4? I don't really know too much about this stuff[/quote]
[quote=fatswimdude]if anyone can figure out a way to use this as an excuse for missing rockets let me know[/quote]
[quote=cme]do u get better ping or what[/quote]
wont affect network quality, just means we can finally add more devices to the internet and NATs are finally not required
The main feature is they went from 32-bit addresses to 128-bit addresses.
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or 340 undecillion 282 decillion 366 nonillion 920 octillion 938 septillion 463 sextillion 463 quintillion 374 quadrillion 607 trillion 431 billion 768 million 211 thousand 456. However, I've seen estimates where end users might be allocated around 4,000 addresses. Anyway, It's going to be a while before we run out of IP addresses again.
The main feature is they went from 32-bit addresses to 128-bit addresses.
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or 340 undecillion 282 decillion 366 nonillion 920 octillion 938 septillion 463 sextillion 463 quintillion 374 quadrillion 607 trillion 431 billion 768 million 211 thousand 456. However, I've seen estimates where end users might be allocated around 4,000 addresses. Anyway, It's going to be a while before we run out of IP addresses again.
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or 340 undecillion 282 decillion 366 nonillion 920 octillion 938 septillion 463 sextillion 463 quintillion 374 quadrillion 607 trillion 431 billion 768 million 211 thousand 456. However, I've seen estimates where end users might be allocated around 4,000 addresses. Anyway, It's going to be a while before we run out of IP addresses again.
NewbieMcNewbfaceBasically they went from 32-bit addresses to 128-bit addresses.
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or three hundred and forty undecillion, two hundred and eighty-two decillion, three hundred and sixty-six nonillion, nine hundred and twenty octillion, nine hundred and thirty-eight septillion, four hundred and sixty-three sextillion, four hundred and sixty-three quintillion, three hundred and seventy-four quadrillion, six hundred and seven trillion, four hundred and thirty-one billion, seven hundred and sixty-eight million, two hundred and eleven thousand, four hundred and fifty-six. It's going to be a while before we run out of IP addresses again.
I see lots of numbers but I don't know what they mean
[quote=NewbieMcNewbface]Basically they went from 32-bit addresses to 128-bit addresses.
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or three hundred and forty undecillion, two hundred and eighty-two decillion, three hundred and sixty-six nonillion, nine hundred and twenty octillion, nine hundred and thirty-eight septillion, four hundred and sixty-three sextillion, four hundred and sixty-three quintillion, three hundred and seventy-four quadrillion, six hundred and seven trillion, four hundred and thirty-one billion, seven hundred and sixty-eight million, two hundred and eleven thousand, four hundred and fifty-six. It's going to be a while before we run out of IP addresses again.[/quote]
I see lots of numbers but I don't know what they mean
The number of ipv4 addresses is 2^32, or 4,294,967,296. They are written in a format such as xxx . xxx . xxx . xxx Depending on the class (A, B, C, D, E, although most people only dealt with the first 3), the ip address could be divided into a network portion and host portion. A company with a class A ip address block could theoretically have 16,777,216 addresses, while a company with a class B address block would only have 65,536.
IPV6 uses an xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx:xxxx format. IPV6 has 2^128 addresses, with the IANA releasing 2^125 for public addressing use. So 42 undecillion out of 340 undecillion. 2^128 is 340,282,366,920,938,463,463,374,607,431,768,211,456 or three hundred and forty undecillion, two hundred and eighty-two decillion, three hundred and sixty-six nonillion, nine hundred and twenty octillion, nine hundred and thirty-eight septillion, four hundred and sixty-three sextillion, four hundred and sixty-three quintillion, three hundred and seventy-four quadrillion, six hundred and seven trillion, four hundred and thirty-one billion, seven hundred and sixty-eight million, two hundred and eleven thousand, four hundred and fifty-six. It's going to be a while before we run out of IP addresses again.[/quote]
I see lots of numbers but I don't know what they mean
On mumble with m8s trying to host a game server:
"Hey man what's your IP?"
"uhh its 493543:5435345#534:fgfdksofd:43534fgg:gfdgfdg43t:fd34dv"
"can u repeat dat m8?"
rip
On mumble with m8s trying to host a game server:
"Hey man what's your IP?"
"uhh its 493543:5435345#534:fgfdksofd:43534fgg:gfdgfdg43t:fd34dv"
"can u repeat dat m8?"
rip
"Hey man what's your IP?"
"uhh its 493543:5435345#534:fgfdksofd:43534fgg:gfdgfdg43t:fd34dv"
"can u repeat dat m8?"
rip
nopeNewbieMcNewbfaceTLDRI see lots of numbers but I don't know what they mean
Number of IPv4 addresses:
4,294,967,296
Number of IPv6 addresses:
340,282,366,920,938,463,463,374,607,431,768,211,456
Think of every computer, cell phone, or internet enabled device. Each one has a public IP address. With 4.294 billion addresses for 7.125 billion people, you can see how a shortage would arise. IPv6 set out to solve this, along with several other issues.
[quote=nope][quote=NewbieMcNewbface]TLDR[/quote]
I see lots of numbers but I don't know what they mean[/quote]
Number of IPv4 addresses:
4,294,967,296
Number of IPv6 addresses:
340,282,366,920,938,463,463,374,607,431,768,211,456
Think of every computer, cell phone, or internet enabled device. Each one has a public IP address. With 4.294 billion addresses for 7.125 billion people, you can see how a shortage would arise. IPv6 set out to solve this, along with several other issues.
I see lots of numbers but I don't know what they mean[/quote]
Number of IPv4 addresses:
4,294,967,296
Number of IPv6 addresses:
340,282,366,920,938,463,463,374,607,431,768,211,456
Think of every computer, cell phone, or internet enabled device. Each one has a public IP address. With 4.294 billion addresses for 7.125 billion people, you can see how a shortage would arise. IPv6 set out to solve this, along with several other issues.
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