One document matched: draft-ietf-iptel-rfc2806bis-01.txt
Differences from draft-ietf-iptel-rfc2806bis-00.txt
Internet Engineering Task Force
Internet Draft H. Schulzrinne/A. Vaha-Sipila
Columbia U./Nokia
draft-ietf-iptel-rfc2806bis-01.txt
June 24, 2003
Expires: December 2003
The tel URI for Telephone Numbers
STATUS OF THIS MEMO
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Abstract
This document specifies the URI (Uniform Resource Identifier) scheme
"tel". The "tel" URI describes resources identified by telephone
numbers.
1 Terminology
In this document, the key words "MUST", "MUST NOT", "REQUIRED",
"SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY",
and "OPTIONAL" are to be interpreted as described in RFC 2119 [1] and
indicate requirement levels for compliant implementations.
2 Introduction
This document defines the URI scheme "tel". The "tel" URI describes
resources identified by telephone numbers. A telephone number is a
string of decimal digits that uniquely indicates the network
termination point. The number contains the information necessary to
route the call to this termination point. (This definition is derived
from [4], but encompasses both public and private numbers.)
The "tel" URI telephone number is not restricted in the type of
termination point it refers to. The termination point can be in the
public telephone network, a private telephone network or the
Internet. The termination point can be a mobile or a fixed wired
terminal. The terminal addressed can support voice, data or fax. The
URI can refer to resources identified by a telephone number,
including but not limited to originators or targets of a telephone
call.
The "tel" URI is a globally unique identifier ("name") only; it does
not describe the steps necessary to reach a particular number and
does not imply dialing semantics. Furthermore, it does not refer to a
specific physical device, only to a telephone number.
Telephone numbers as commonly understood actually comprise two
related, but distinct concepts: as a canonical address-of-record and
as a dial-string. We define the concepts below:
Address-of-record or identifier: The telephone number is
understood here as the canonical address-of-record or
identifier for a public network termination point. Public
numbers follow the rules in E.164 [4], while private
numbers follow the rules of the owner of the private
numbering plan. Subscribers publish such identifiers phone
number as a universal means of being reached, independent
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of the location of the caller. (Naturally, not all numbers
are reachable from everywhere, for a variety of technical
and local policy reasons.)
Dial string: "Dial strings" are the actual numbers, symbols and
pauses entered by a user to place a phone call. A dial-
string is consumed by one or more network entities, and
understood in the context of the configuration of these
entities. It is used to generate a telephone number so that
a call can be routed. Dial-strings may require pre-pended
digits to handle local PBXs, and they may include post-dial
DTMF signaling that could control an IVR or reach an
extension. Dial strings are beyond the scope of this
document.
To reach a telephone number from a particular terminal, the user of
the terminal or the terminal itself has to know how to convert the
telephone number identifier into a dial string appropriate for that
terminal. The telephone number itself does not convey what needs to
be done for a particular terminal. Instructions may include dialing
"9" before placing a call or prepending a "00" to reach a number in a
foreign country. The terminal may also need to strip area and country
codes.
The notation for phone numbers in this document is similar to that in
RFC 3191 [5] and RFC 3192 [6]. However, the syntax differs since
this document describes URIs whereas RFC 3191 and RFC 3192 specify
electronic mail addresses. RFC 3191 and RFC 3192 use "/" to indicate
parameters (qualifiers). Since URI use the forward slash to describe
path hierarchy, the URI scheme described here uses the semicolon, in
keeping with Session Initiation Protocol (SIP) URI conventions [7].
There are at least two ways one can envision making a telephone
connection. In the first approach, a URI contains the dial string,
which is then passed to an entity that can reproduce the actions
specified in the dial string. For example, in an analog phone system,
a dialer translates the dial string into a sequence of actions such
as waiting for dial tone, sending DTMF digits, pausing and generating
post-dial DTMF digits after the callee picks up. In an ISDN or ISUP
environment, the recipient of the dial string performs the
appropriate protocol actions.
Another approach has the URI specify the telephone number, which can
be either globally unique or only be valid within a local context.
The dialing application is aware of the local context, knowing, for
example, whether special digits need to be dialed to seize an outside
line, whether network, pulse or tone dialing is needed and what tones
indicate call progress. The dialing application then converts the
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telephone number into a dial sequence and performs the necessary
signaling actions. The document below assumes the second model. The
dialer does not have to be a user application as found in traditional
desktop operating systems, but could well be part of an IP-to-PSTN
gateway.
The approach pursued here has the disadvantage that certain services,
such as electronic banking or voicemail, cannot be specified in a
URI.
The URI can be used as a request URI in SIP [7] requests. The SIP
specification also inherits the subscriber part of the syntax as part
of the user element in the SIP URI. Other protocols may use this URI
for both query-based and prefix-based applications.
The "tel" URI does not specify the call type such as voice, fax, or
data call and does not provide the connection parameters for a data
call. The type and parameters are assumed to be negotiated either
in-band by the telephone device or through a signaling protocol such
as SIP.
3 URI Syntax
The URI is defined using the ABNF (augmented Backus-Naur form)
described in RFC 2234 [2] and uses elements from the core definitions
(Appendix A of RFC 2234).
The syntax definition follows RFC 2396 [3], indicating the actual
characters contained in the URI. Note that the reserved characters
"+", ";", "=", and "?" MUST NOT be escaped if shown in the grammar
definitions below as they are delimiters for the "tel" URI scheme.
These reserved characters MUST be escaped if they appear in parameter
values.
Characters other than those in the "reserved" and "unsafe" sets (see
RFC 2396 [3]) are equivalent to their "% HEX HEX" encoding.
The "tel" URI has the following syntax:
telephone-uri = "tel:" telephone-subscriber |
telephone-subscriber = global-number / local-number |
global-number = global-number-digits *par |
local-number = local-number-digits *par context *par |
par = parameter / extension / isdn-subaddress |
isdn-subaddress = ";isub=" 1*uric |
extension = ";ext=" 1*phonedigit |
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context = ";phone-context=" descriptor |
descriptor = domainname / global-number-digits |
global-number-digits = "+" 1*phonedigit |
local-number-digits = 1*phonedigit-hex |
domainname = *( domainlabel "." ) toplabel [ "." ] |
domainlabel = alphanum |
/ alphanum *( alphanum / "-" ) alphanum |
toplabel = ALPHA / ALPHA *( alphanum / "-" ) alphanum |
parameter = ";" pname ["=" pvalue ] |
pname = 1*( alphanum / "-" ) |
pvalue = 1*paramchar |
paramchar = param-unreserved / unreserved / escaped |
unreserved = alphanum / mark |
escaped = "%" HEXDIG HEXDIG |
param-unreserved = "[" / "]" / "/" / ":" / "&" / "+" / "$" |
phonedigit = DIGIT [ visual-separator ] |
phonedigit-hex = HEXDIG [ visual-separator ] |
visual-separator = "-" / "." / "(" / ")" |
alphanum = ALPHA / DIGIT |
Each parameter name ("pname"), the ISDN subaddress, the extension and
the context MUST NOT appear more than once. The order of the URL
parameters is immaterial. The ISDN subaddress or extension SHOULD
appear first, if present, followed by the context parameter, if
present, followed by any other parameters in lexicographical order.
This simplifies comparison when the "tel" URI is compared
character-by-character, such as in SIP URIs [7].
4 URI Comparisons
Two "tel" URIs are equivalent according to the following rules:
o URI are not equal if one is a <local-number> and the other a
<global-number>.
o For mandatory extension parameters and the <phone-context> and
<extension> parameters defined in this document, <phone-
number> parameter values are compared digit-by-digit after
removing all <visual-separator>s from consideration.
o Parameters are compared according to <pname>, regardless of
the order they appeared in the URI. If one URI has a parameter
name not found in the other, the two URIs are not equal.
o URI comparisons are case-insensitive.
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All parameter names and values SHOULD use lower-case characters since
tel URIs may be used within contexts where comparisons are case-
sensitive.
Section 19.1.4 in the SIP specification [7] discusses one
such case.
5 Phone Numbers and Their Context
5.1 Phone Numbers
The <subscriber> part of the URI indicates the number. The phone
number can be represented in either global (E.164) or local notation.
All phone numbers MUST use the global form unless they cannot be
represented as such. Numbers from private numbering plans, emergency
("911", "112") and some directory assistance numbers (e.g., "411")
and other "service codes" (numbers of the form N11 in the United
States) cannot be represented in global (E.164) form, and need to be
represented as a local number with a context. Local numbers MUST be
tagged with a phone-context (Section 5.1.4).
Implementations MUST NOT assume that telephone numbers have a
maximum, minimum or fixed length, or that they always begin with a
certain number.
E.164 limits numbers to 15 digits. For geographic numbers,
one to three digits are the country code, with the
remainder divided into area or city code (national
destination code) and subscriber number. Alternatively,
there is a global three-digit service code, followed by a
global subscriber number of up to 12 digits. Finally, a
"international public telecommunication number for networks
is composed of decimal digits arranged in three code
fields. The code fields are the 3-digit shared Country Code
(CC) field, the IC field, which varies in length between 1
to 4 digits, and the Subscriber Number (SN) which can be up
to 15 minus the number of digits in the CC and IC fields."
[4]
5.1.1 Separators in Phone Numbers
Phone numbers MAY contain visual separators. Visual separators
(<visual-separator>) merely aid readability and are not used for URI
comparison or placing a call.
Despite complicating comparisons, this specification
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retains the visual separators to follow the spirit of RFC
2396 [3], which remarks that "A URI often needs to be
remembered by people, and it is easier for people to
remember a URI when it consists of meaningful components."
Also, ISBN URNs documented in RFC 3187 [8] use visual
separators in a manner similar to this specification.
Even though ITU-T E.123 [9] recommends the use of space
characters as visual separators in printed telephone
numbers, "tel" URIs cannot use spaces to avoid excessive
escaping.
5.1.2 Alphabetic Characters
In some countries, it is popular to write phone numbers using
alphabetic characters which correspond to certain numbers on the
telephone keypad. The URI format does not support this notation
since the mapping from alphabetic characters to digits is not
completely uniform internationally, although there are standards
[10,11] addressing this issue.
Since called and calling terminal numbers (TNs) are encoded in BCD in
ISUP, this allows for six additional values per digit, sometimes
represented as the hexadecimal characters A through F. However, in
accordance with E.164, they may not be included in global numbers.
Their use in local numbers is not defined, but is not prohibited.
The non-numeric DTMF symbols A, B, C and D are part of dial strings,
not identifiers, and thus are not appropriate for encoding in "tel"
URIs.
5.1.3 Global Numbers
Globally unique numbers are identified by the leading "+" character.
Global numbers MUST be composed with the country (CC) and national
(NSN) numbers as specified in E.123 and E.164 [9,4]. Globally unique
numbers have the property of being unambiguous everywhere in the
world and are RECOMMENDED.
5.1.4 Local Numbers |
Local numbers are unique only within a certain geographical area or a |
certain part of the telephone network, e.g., a private branch |
exchange (PBX), a state or province, a particular local exchange |
carrier or a particular country. URIs with local phone numbers should |
only appear in environments where all local entities can successfully |
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set up the call by passing the number to the dialing software. Digits |
needed for accessing an outside line, for example, are not included |
in local numbers. Local numbers SHOULD NOT be used unless there is no |
way to represent the number as a global number. |
Local numbers require that the originator and recipient are |
configured appropriately, so that they can insert and |
recognize the correct descriptors. Since there is no |
algorithm to independently pick the same descriptor, |
labeling numbers with their context increases the chances |
of mis-configuration, so that valid identifiers are |
rejected by mistake. The algorithm to select descriptors |
was chosen that accidental collisions should be rare, but |
they cannot be ruled out. |
Local numbers MUST have a phone-context parameter that identifies the |
scope of their validity. The parameter MUST be chosen to |
unambiguously identify the local context within which the number is |
unique. Thus, the combination of the descriptor in the phone-context |
parameter and local number is again globally unique. The parameter |
value is defined by the assignee of the local number. It does NOT |
indicate a prefix that turns the local number into a global (E.164) |
number. |
There are two ways to label the context: via a global number or any |
number of its leading digits (e.g., "+33") and via a domain name, |
e.g., "houston.example.com". The choice between the two is left to |
the "owner" of the local number and is governed by whether there is a |
global number or domain name that is a valid identifier for a |
particular local number. |
The domain name does not have to resolve to any actual host, but MUST |
be under the administrative control of the entity managing the local |
phone context. |
A global number context consists of the initial digits of a valid |
global number. All global numbers matching these initial digits must |
be assigned to the same organization that is describing the context |
and no such matching number can be used by any other organization. If |
such an initial string of digits does not exist, the organization |
should use the lowest number of the global number range assigned to |
it. (This can occur if two organizations share the same decimal block |
of numbers. For example, assume an organization owns the number range |
+1-212-939-7000 through +1-212-939-7199. +1-212-939-7 would not be a |
valid global number context, but +1-212-939-7000 would work.) It is |
not required that local numbers within the context actually begin |
with the chosen set of initial numbers. |
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For a local number defined within a PBX, the organization can choose |
any number under its control to identify the context. For example, a |
context consisting of any of the organization's global numbers may be |
suitable, or a substring that is completely occupied by the |
organization. For example, +49-6151-16 would be a suitable context |
for the TU Darmstadt, as it uses all numbers starting with those |
digits. |
A context consisting of the initial digits of a global number does |
not imply that adding these to the local number will generate a valid |
E.164 number. It might do so by coincidence, but this cannot be |
relied upon. (For example, "911" should be labeled with the context |
"+1", but "+1-911" is not a valid E.164 number.) |
National freephone numbers do not need a context, even though they |
are not necessarily reachable from outside a particular country code |
or numbering plan. Recall that "tel" URIs are identifiers; it is |
sufficient that a global number is unique, but it is not required |
that it be reachable from everywhere. |
Even non-freephone numbers may be out of date or not be |
reachable from a particular location. For example, premium |
services such as "900" numbers in the North American |
numbering plan are often not dialable from outside the |
particular country code.
The two label types were chosen so that, in almost all
cases, a local administrator can pick an identifier that is
reasonably descriptive and does not require a new IANA-
managed assigned number. It is up to the administrator to
assign an appropriate identifier and to use it
consistently. Often, an organization can choose among
several different identifiers.
If the recipient of a "tel" URI uses the URI simply for
identification, the receiver does not need to know anything about the
context descriptor. It simply treats it as one part of a globally
unique identifier, with the other being the local number. If a
recipient of the URI intends to place a call to the local number, it
MUST verify that it is within the same context as one of the
descriptors. If it is not within the same context, it MUST NOT
initiate the call and treat the URI like an invalid destination.
5.2 ISDN Subaddresses
A phone number MAY also contain an <isdn-subaddress> parameter which
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indicates an ISDN subaddress.
ISDN subaddresses typically contain IA5 characters, but may contain
any octet value.
5.3 Extensions |
Extensions identify stations behind a PBX and are roughly equivalent |
to ISDN subaddresses. They are identified with the <extension> |
parameter. At most one of the <isdn-subaddress> and <extension> |
parameters can appear in a tel URI, i.e., they cannot appear both at |
the same time. |
5.4 Other Parameters
Future extensions to this URI scheme may add other parameters
(<parameter> in the ABNF). Such parameters can be either mandatory or
optional. Mandatory parameters start with "m-". An implementation MAY
ignore optional parameters. An implementation MUST NOT use the URI if
it contains unknown mandatory parameters. The "m-" prefix cannot be
added to parameters that were already registered (except to create a
new, logically distinct parameter). The "phone-context" parameter in
this document is mandatory.
For example, <parameter> parameters can be used to store
application-specific additional data about the phone number, its
intended use, or any conversions that have been applied to the
number.
All new parameters MUST be registered with IANA.
6 Examples
tel:+358-555-1234567
This URI points to a phone number in Finland. The hyphens
are included to make the number more human-readable; they
separate country, area codes and subscriber number.
tel:7042;phone-context=cs.columbia.edu
The URI describes a local phone number valid within the
context "cs.columbia.edu".
tel:863-1234;phone-context=+1-914-784
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The URI describes a local phone number that is valid within
a particular phone prefix.
7 Rationale
7.1 Why Not Just Put Telephone Numbers in SIP URIs?
The "tel" URI describes a service, reaching a telephone number, that
is independent of the means of doing so, be it via a SIP-to-PSTN
gateway, a direct SIP call via ENUM translation, some other signaling
protocols such as H.323 or a traditional circuit-switched call
initiated on the client side via, say, TAPI. It is thus, in spirit,
closer to the URN schemes that also leave the resolution to an
external mechanism. The same "tel" URI may get translated to any
number of other URIs in the process of setting up the call.
7.2 Why Not Distinguish Between Call Types?
Signaling protocols such as SIP allow to negotiate the call type and
parameters, making the very basic indication within the URL scheme
moot. Also, since the call type can change frequently, any such
indication in a URI is likely to be out of date. If such designation
is desired for a device that directly places calls without a
signaling protocol such as SIP, mechanisms such as the "type"
attribute for the "A" element in HTML may be more appropriate.
7.3 Why "tel"?
"Tel" was chosen since it is widely recognized none of the other
suggestions appeared appropriate. "Callto" was discarded since URI
schemes locate a resource and do not specify an action to be taken.
"Telephone" and "phone" were considered too long and not as
internationally recognized.
7.4 Do Not Confuse Numbers with How They Are Dialed
As an example, the E.164 number "+1-212-555-3141" will be dialed in
many countries as 00-1-212-555-3141, where the leading "00" is a
prefix for international calls. (In general, "+" in E.164 indicates
that an international prefix is required.) Tel URIs MUST NOT contain
the local dialing prefixes in numbers such as +1-212-555-3141, as the
transformation back to an international number is not guaranteed to
be correct or unique.
If a network entity receives a "tel" URI containing a local number,
it MUST make sure that it knows the context in which the local phone
number is to be processed, or else the number MUST NOT be used.
Equally, the originator of a "tel" URI must take into consideration
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that the recipient may have insufficient information about the phone
number's context.
8 Usage of Telephone URIs in HTML
Links using the "tel" URL SHOULD enclose the telephone number, so
that users can easily predict the action taken when following the
link.
Dial <a href="tel:+3585551234567">+358-555-1234567</a> for assistance.
instead of
Dial <a href="tel:+3585551234567">this number</a> for assistance.
On a public HTML page, the telephone number in the URI SHOULD always
be in the global form, even if the text of the link uses some local
format.
Telephone (if dialing in Finland):
<a href="tel:+3585551234567">(0555) 1234567</a>
or even
For having RFCs read aloud, call
<a href="tel:+1-555-438-3732">1-555-IETF-RFC</a>.
9 IANA Considerations
"Tel" URI parameters (<parameter>) MUST be registered with IANA.
Mandatory parameters must be described in a standards-track RFC,
while an informational RFC is sufficient for other parameters.
The registration must indicate:
o the parameter name;
o a description of its applicability;
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o whether the parameter is mandatory or not ( Only the names of
mandatory parameters must start with "m-" as described in
Section 5.4.);
o restrictions on the syntax of the parameter value in ABNF
form;
o a reference to the specification that defines it.
10 Security Considerations
The security considerations parallel those for the mailto URL [12].
A recipient of a "tel" URI SHOULD NOT place calls without the consent
of its owner. Placing calls automatically without appropriate user
confirmation may incur a number of risks, such as those described
below.
o Calls may incur costs.
o The URI may be used to place malicious or annoying calls.
o A call will take the user's phone line off-hook, thus
preventing its use.
o A call may reveal the user's, possibly unlisted, phone number
to the remote host in the caller identification data, and may
allow the attacker to correlate the user's phone number with
other information such as the e-mail or IP address.
o A call may use the same local number in different contexts, in
which the number may have a different meaning.
A Use of "tel" URIs with SIP (Informative)
SIP can use the "tel" URI as a Request-URI, along with "sip" and
"sips" URIs. For brevity, we will imply "sips" URIs when talking
about SIP URIs. Both "tel" and SIP URIs can contain telephone
numbers. In SIP URIs, they appear as the user part, i.e., before the
@ symbol (Section 19.1.6 in [7]).
Unless a SIP UA connects directly to a PSTN gateway, one of the SIP
proxy servers has to translate the tel URI to a SIP URI, with the
host part of that URI pointing to a gateway. Typically, the outbound
proxy server, as the first proxy server visited by a call request,
performs this translation. A proxy server can translate all tel URIs
to the same SIP host name or select a different gateway for different
tel prefixes, based, for example, on information learned from TRIP.
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However, a proxy server could also delegate this translation task to
any other proxy server since proxy servers are free to apply whatever
routing logic they desire.
As noted earlier, all phone numbers MUST use the global form unless
they cannot be represented as such. If the local-number format is
used, it MUST be qualified by the phone-context parameter.
Effectively, the combination of local number and phone context makes
the tel URI globally unique.
While web pages, vCard business cards, address books and directories
can easily contain global tel URIs, users on twelve-button (IP)
phones cannot dial such numbers directly and are typically accustomed
to dialing shorter strings, e.g., for PBX extensions or local
numbers. These so-called dial-strings (Section 2) are not directly
represented by tel URIs, as noted. We refer to the translation of
dial strings into SIP and tel URIs, global or local, as the dial
plan. There are at least two appropriate ways to deal with dial
strings in SIP terminals:
Local translation: A SIP UA can use a dial plan to translate
dial strings into SIP or "tel" URIs. The dial plan can be
manually configured or, preferably, be downloaded as part
of a device configuration mechanism. (At this time, there
is no standardized mechanism for this.)
A mobile user can use at least two dial plans, namely the
dial plan for the network that he is currently visiting and
the dial plan for the user's home network. Generally,
dialed numbers that are meant to represent global numbers
will look the same after the translation regardless of the
dial plan, even if, say, the visited network uses '0' for
dialing an 'outside' number and the user's home network
uses '9', as long as the user is aware of the current dial
plan. However, local extensions that do not have a direct
global equivalent may well behave differently. To avoid any
ambiguity, the dial plan MUST insert a suitable phone-
context string when performing the translation. If the
phone-context is a domain name, there are three cases:
1. The outbound proxy recognizes the domain name in the
SIP URI as its local context and can route the request
to a gateway that understands the local number.
2. The outbound proxy does not use the same phone
context, but can route to a proxy that handles this
phone context. This routing can be done via a lookup
table or the domain name of the phone context might be
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set up to reflect the SIP domain name of a suitable
proxy. For example, a proxy may always route calls
with tel URIs like
tel:1234;phone-context=munich.example.com
to the SIP proxy located at munich.example.com.
(Proxies that receive a tel URI with a context they do
not understand are obligated to return a 404 (Not
Found) status resonse, so that an outbound proxy may
decide to attempt such a heuristic.)
3. The outbound proxy does not recognize the phone
context and cannot find the appropriate proxy
cognizant of that phone context. In that case, the
translation fails and the outbound proxy returns a 404
(Not Found) error response.
Proxy translation: In proxy translation mode, the SIP UA simply
turns the dialed digits into the user part of the SIP URI
and appends a ;user=phone parameter and provides an
appropriate phone context reflecting the local dialing
plan. The host name or IP address of the outbound proxy is
made the host part of the SIP request URI. The outbound
proxy can then apply its local dial plan to translate the
SIP URI into a "tel" URI or other SIP URI. Translation into
a "tel" URI makes sense only if the proxy wants to delegate
finding the PSTN gateway to another proxy.
For example, after the user with a location-specified dial
plan located in domain "munich.example.com" dials the
digits "1234", the device converts this into a SIP URI:
sip:1234;phone-context=munich.example.com@example.com
Alternatively, the SIP UA can issue a call with a "tel"
URI. For this example, it might be:
tel:1234;phone-context=munich.example.com
H. Schulzrinne/A. Vaha-Sipila [Page 15]
Internet Draft The tel URI June 24, 2003
Using a SIP URI is more robust and is thus the preferred
approach.
Since a single proxy may receive calls from many
difference locations with different local dial plans,
devices that rely on the proxy for number translation
SHOULD always be configured with a context. Otherwise,
a provider or enterprise would have to provision a
separate proxy for each branch office or geographic
area with its own dial plan, for example.
B Change History
B.1 Changes from ietf-00 to ietf-01
o Editorial changes suggested by Francois Audet.
B.2 Changes from -08 to draft-ietf-iptel-rfc2806bis-00
o Editorial clarifications.
o Remove multiple context descriptions.
B.3 Changes Since -07
o Added section on using tel URIs in SIP.
B.4 Changes Since -06
o Clarified semantics.
o Removed context from freephone numbers.
o Added phone extensions.
B.5 Changes Since -05
o URI comparisons are case-insensitive.
o Specified recommended order of parameters to simplify use
within SIP URIs.
B.6 Changes Since -04
o ISDN subaddresses can contain any IA5 character or even binary
data; represented now as "uric".
H. Schulzrinne/A. Vaha-Sipila [Page 16]
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B.7 Changes Since -03
o Clarified use of multiple contexts and how to express this, as
a comma-separated list.
B.8 Changes Since -02
o Clarifications and editorial fixes.
o Now, mandatory parameters are labeled, to avoid making [13]
obsolete.
B.9 Changes Since -01
The draft has been greatly simplified to reflect parts that have
actually been implemented.
o Removed references to carrier selection.
o Removed dial context.
o Removed fax and modem URIs.
o Removed post-dial strings.
o Removed pause characters.
B.10 Changes Since RFC 2806
The specification is backwards-compatible with RFC 2806.
o Editorial changes and clarifications. The document has been
shortened and reorganized. Most paragraphs have been rewritten
to be more concise.
o Syntax now conforms to RFC 2396 [3], in particular related to
escaping.
C Acknowledgments
This document inherits a large amount of text from RFC 2806 [14].
Flemming Andreasen, Francois Audet, Lawrence Conroy, Andrew Main,
Michael Hammer, Jon Peterson, Mike Pierce, Jonathan Rosenberg and
James Yu provided extensive comments.
D References
E Normative References
H. Schulzrinne/A. Vaha-Sipila [Page 17]
Internet Draft The tel URI June 24, 2003
[1] S. Bradner, "Key words for use in RFCs to indicate requirement
levels," RFC 2119, Internet Engineering Task Force, Mar. 1997.
[2] D. Crocker and P. Overell, eds., "Augmented BNF for syntax
specifications: ABNF," RFC 2234, Internet Engineering Task Force,
Nov. 1997.
[3] T. Berners-Lee, R. Fielding, and L. Masinter, "Uniform resource
identifiers (URI): generic syntax," RFC 2396, Internet Engineering
Task Force, Aug. 1998.
F Informative References
[4] International Telecommunication Union, "The international public
telecommunication numbering plan," Recommendation E.164,
Telecommunication Standardization Sector of ITU, Geneva, Switzerland,
May 1997.
[5] C. Allocchio, "Minimal GSTN address format in internet mail," RFC
3191, Internet Engineering Task Force, Oct. 2001.
[6] C. Allocchio, "Minimal FAX address format in internet mail," RFC
3192, Internet Engineering Task Force, Oct. 2001.
[7] J. Rosenberg, H. Schulzrinne, G. Camarillo, A. Johnston, J.
Peterson, R. Sparks, M. Handley, and E. Schooler, "SIP: session
initiation protocol," RFC 3261, Internet Engineering Task Force, June
2002.
[8] J. Hakala and H. Walravens, "Using international standard book
numbers as uniform resource names," RFC 3187, Internet Engineering
Task Force, Oct. 2001.
[9] International Telecommunication Union, "Notation for national and
international phone numbers," Recommendation E.123, Telecommunication
Standardization Sector of ITU, Geneva, Switzerland, 1998.
[10] International Telecommunication Union, "Arrangement of digits,
letters and symbols on telephones and other devices that can be used
for gaining access to a telephone network," Recommendation E.161,
Telecommunication Standardization Sector of ITU, Geneva, Switzerland,
May 1995.
[11] ANSI, "Allocation of letters to the keys of numeric keypads for
telecommunications," Standard T1.703-1995 (R1999), ANSI, 1999.
[12] P. Hoffman, L. Masinter, and J. Zawinski, "The mailto URL
scheme," RFC 2368, Internet Engineering Task Force, July 1998.
H. Schulzrinne/A. Vaha-Sipila [Page 18]
Internet Draft The tel URI June 24, 2003
[13] J. Yu, "Extensions to the 'tel' URL to support number
portability and freephone service," Internet Draft, Internet
Engineering Task Force, Aug. 2002. Work in progress.
[14] A. Vaha-Sipila, "URLs for telephone calls," RFC 2806, Internet
Engineering Task Force, Apr. 2000.
G Authors' Addresses
Henning Schulzrinne
Dept. of Computer Science
Columbia University
1214 Amsterdam Avenue
New York, NY 10027
USA
electronic mail: schulzrinne@cs.columbia.edu
Antti Vaha-Sipila
(ISO 8859-15 quoted-printable: Antti V=E4h=E4-Sipil=E4)
Nokia Mobile Phones
P. O. Box 321
FIN-00045 Nokia Group
Finland
electronic mail: avs@iki.fi, antti.vaha-sipila@nokia.com
H Full Copyright Notice
The IETF takes no position regarding the validity or scope of any
intellectual property or other rights that might be claimed to
pertain to the implementation or use of the technology described in
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might or might not be available; neither does it represent that it
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claims of rights made available for publication and any assurances of
licenses to be made available, or the result of an attempt made to
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proprietary rights by implementors or users of this specification can
be obtained from the IETF Secretariat.
The IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights which may cover technology that may be required to practice
this standard. Please address the information to the IETF Executive
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This document and translations of it may be copied and furnished to
H. Schulzrinne/A. Vaha-Sipila [Page 19]
Internet Draft The tel URI June 24, 2003
others, and derivative works that comment on or otherwise explain it
or assist in its implmentation may be prepared, copied, published and
distributed, in whole or in part, without restriction of any kind,
provided that the above copyright notice and this paragraph are
included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
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The limited permissions granted above are perpetual and will not be
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This document and the information contained herein is provided on an
"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
H. Schulzrinne/A. Vaha-Sipila [Page 20]
Table of Contents
1 Terminology ......................................... 2
2 Introduction ........................................ 2
3 URI Syntax .......................................... 4
4 URI Comparisons ..................................... 5
5 Phone Numbers and Their Context ..................... 6
5.1 Phone Numbers ....................................... 6
5.1.1 Separators in Phone Numbers ......................... 6
5.1.2 Alphabetic Characters ............................... 7
5.1.3 Global Numbers ...................................... 7
5.1.4 Local Numbers .....7................................. |
5.2 ISDN Subaddresses ................................... 9
5.3 Extensions .....10................................... |
5.4 Other Parameters .................................... 10
6 Examples ............................................ 10
7 Rationale ........................................... 11
7.1 Why Not Just Put Telephone Numbers in SIP URIs?
................................................................ 11
7.2 Why Not Distinguish Between Call Types? ............ 11
7.3 Why "tel"? ......................................... 11
7.4 Do Not Confuse Numbers with How They Are Dialed ..... 11
8 Usage of Telephone URIs in HTML ..................... 12
9 IANA Considerations ................................. 12
10 Security Considerations ............................. 13
A Use of "tel" URIs with SIP (Informative) ............ 13
B Change History ...................................... 16
B.1 Changes from ietf-00 to ietf-01 ..................... 16
B.2 Changes from -08 to draft-ietf-iptel-rfc2806bis-00
................................................................ 16
B.3 Changes Since -07 ................................... 16
B.4 Changes Since -06 ................................... 16
B.5 Changes Since -05 ................................... 16
B.6 Changes Since -04 ................................... 16
B.7 Changes Since -03 ................................... 17
B.8 Changes Since -02 ................................... 17
B.9 Changes Since -01 ................................... 17
B.10 Changes Since RFC 2806 .............................. 17
C Acknowledgments ..................................... 17
D References .......................................... 17
E Normative References ................................ 17
F Informative References .............................. 18
G Authors' Addresses .................................. 19
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H Full Copyright Notice ............................... 19
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