RFC2806


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Network Working Group A. Vaha-Sipila Request for Comments: 2806 Nokia Category: Standards Track April 2000 URLs for Telephone Calls Status of this Memo This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited. Copyright Notice Copyright (C) The Internet Society (2000). All Rights Reserved. Abstract This document specifies URL (Uniform Resource Locator) schemes "tel", "fax" and "modem" for specifying the location of a terminal in the phone network and the connection types (modes of operation) that can be used to connect to that entity. This specification covers voice calls (normal phone calls, answering machines and voice messaging systems), facsimile (telefax) calls and data calls, both for POTS and digital/mobile subscribers. Table of Contents 1. Introduction ................................................ 2 1.1 New URL schemes ............................................ 2 1.2 Formal definitions ......................................... 3 1.3 Requirements ............................................... 3 2. URL schemes for telephone calls ............................. 3 2.1 Applicability .............................................. 3 2.2 "tel" URL scheme ........................................... 4 2.3 "fax" URL scheme ........................................... 6 2.4 "modem" URL scheme ......................................... 6 2.5 Parsing telephone, fax and modem URLs ...................... 7 2.5.1 Call type ................................................ 7 2.5.2 Phone numbers and their scope ............................ 7 2.5.3 Separators in phone numbers .............................. 10 2.5.4 Converting the number to the local numbering scheme ...... 10 2.5.5 Sending post-dial sequence after call setup .............. 10 2.5.6 Pauses in dialing and post-dial sequence ................. 11 2.5.7 ISDN subaddresses ........................................ 11 Vaha-Sipila Standards Track [Page 1]
RFC 2806 URLs for Telephone Calls April 2000 2.5.8 T.33 subaddresses ........................................ 11 2.5.9 Data call parameters ..................................... 12 2.5.10 Telephony service provider identification ............... 13 2.5.11 Additional parameters ................................... 14 2.6 Examples of Use ............................................ 14 2.7 Rationale behind the syntax ................................ 15 2.7.1 Why distinguish between call types? ..................... 15 2.7.2 Why "tel" is "tel"? ..................................... 16 2.7.3 Why to use E.164-style numbering? ........................ 16 2.7.4 Not everyone has the same equipment as you ............... 17 2.7.5 Do not confuse numbers with how they are dialled ......... 17 3. Comments on usage ........................................... 17 4. References .................................................. 18 5. Security Considerations ..................................... 19 6. Acknowledgements ............................................ 20 7. Author's Address ............................................ 20 8. Full Copyright Statement .................................... 21

1. Introduction

1.1 New URL schemes

This specification defines three new URL schemes: "tel", "fax" and "modem". They are intended for describing a terminal that can be contacted using the telephone network. The description includes the subscriber (telephone) number of the terminal and the necessary parameters to be able to successfully connect to that terminal. The "tel" scheme describes a connection to a terminal that handles normal voice telephone calls, a voice mailbox or another voice messaging system or a service that can be operated using DTMF tones. The "fax" scheme describes a connection to a terminal that can handle telefaxes (facsimiles). The name (scheme specifier) for the URL is "fax" as recommended by [E.123]. The "modem" scheme describes a connection to a terminal that can handle incoming data calls. The term "modem" refers to a device that does digital-to-analog and analog-to-digital conversions; in addition to these, a "modem" scheme can describe a fully digital connection. The notation for phone numbers is the same which is specified in [RFC2303] and [RFC2304]. However, the syntax definition is a bit different due to the fact that this document specifies URLs whereas [RFC2303] and [RFC2304] specify electronic mail addresses. For example, "/" (used in URLs to separate parts in a hierarchical URL [RFC2396]) has been replaced by ";". In addition, this URL scheme has been synchronized with [RFC2543]. Vaha-Sipila Standards Track [Page 2]
RFC 2806 URLs for Telephone Calls April 2000 When these URLs are used, the number of parameters should be kept to the minimum, unless this would make the context of use unclear. Having a short URL is especially important if the URL is intended to be shown to the end user, printed, or otherwise distributed so that it is visible.

1.2 Formal definitions

The ABNF (augmented Backus-Naur form) notation used in formal definitions follows [RFC2234]. This specification uses elements from the 'core' definitions (Appendix A of [RFC2234]). Some elements have been defined in previous RFCs. If this is the case, the RFC in question has been referenced in comments. Note on non-unreserved characters [RFC2396] in URLs: the ABNF in this document specifies strings of raw, unescaped characters. If those characters are present in a URL, and are not unreserved [RFC2396], they MUST be escaped as explained in [RFC2396] prior to using the URL. In addition, when parsing a URL, it must be noted that some characters may have been escaped. An example: ABNF notation "%x20" means a single octet with a hexadecimal value of "20" (in US-ASCII, a space character). This must be escaped in a URL, and it becomes "%20". In addition, the ABNF in this document only uses lower case. The URLs are case-insensitive (except for the <future-extension> parameter, whose case-sensitivity is application-specific).

1.3 Requirements

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119]. Compliant software MUST follow this specification.

2. URL schemes for telephone calls

2.1 Applicability

In this document, "local entity" means software and hardware that can detect and parse one or more of these URLs and possibly place a call to a remote entity, or otherwise utilize the contents of the URL. These URL schemes are used to direct the local entity to place a call using the telephone network, or as a method to transfer or store a phone number plus other relevant data. The network in question may be Vaha-Sipila Standards Track [Page 3]
RFC 2806 URLs for Telephone Calls April 2000 a landline or mobile phone network, or a combination of these. If the phone network differentiates between (for example) voice and data calls, or if the local entity has several different telecommunications equipment at its disposal, it is possible to specify which kind of call (voice/fax/data) is requested. The URL can also contain information about the capabilities of the remote entity, so that the connection can be established successfully. The "tel", "fax" and "modem" URL schemes defined here do not use the hierarchical URL syntax; there are no applicable relative URL forms. The URLs are always case-insensitive, except for the <future- extension> parameter (see below), whose case-sensitivity is application specific. Characters in the URL MUST be escaped when needed as explained in [RFC2396].

2.2 "tel" URL scheme

The URL syntax is formally described as follows. For the basis of this syntax, see [RFC2303]. telephone-url = telephone-scheme ":" telephone-subscriber telephone-scheme = "tel" telephone-subscriber = global-phone-number / local-phone-number global-phone-number = "+" base-phone-number [isdn-subaddress] [post-dial] *(area-specifier / service-provider / future-extension) base-phone-number = 1*phonedigit local-phone-number = 1*(phonedigit / dtmf-digit / pause-character) [isdn-subaddress] [post-dial] area-specifier *(area-specifier / service-provider / future-extension) isdn-subaddress = ";isub=" 1*phonedigit post-dial = ";postd=" 1*(phonedigit / dtmf-digit / pause-character) area-specifier = ";" phone-context-tag "=" phone-context-ident phone-context-tag = "phone-context" phone-context-ident = network-prefix / private-prefix network-prefix = global-network-prefix / local-network-prefix global-network-prefix = "+" 1*phonedigit local-network-prefix = 1*(phonedigit / dtmf-digit / pause-character) private-prefix = (%x21-22 / %x24-27 / %x2C / %x2F / %x3A / %x3C-40 / %x45-4F / %x51-56 / %x58-60 / %x65-6F / %x71-76 / %x78-7E) *(%x21-3A / %x3C-7E) ; Characters in URLs must follow escaping rules ; as explained in [RFC2396] Vaha-Sipila Standards Track [Page 4]
RFC 2806 URLs for Telephone Calls April 2000 ; See sections 1.2 and 2.5.2 service-provider = ";" provider-tag "=" provider-hostname provider-tag = "tsp" provider-hostname = domain ; <domain> is defined in [RFC1035] ; See section 2.5.10 future-extension = ";" 1*(token-char) ["=" ((1*(token-char) ["?" 1*(token-char)]) / quoted-string )] ; See section 2.5.11 and [RFC2543] token-char = (%x21 / %x23-27 / %x2A-2B / %x2D-2E / %x30-39 / %x41-5A / %x5E-7A / %x7C / %x7E) ; Characters in URLs must follow escaping rules ; as explained in [RFC2396] ; See sections 1.2 and 2.5.11 quoted-string = %x22 *( "\" CHAR / (%x20-21 / %x23-7E / %x80-FF )) %x22 ; Characters in URLs must follow escaping rules ; as explained in [RFC2396] ; See sections 1.2 and 2.5.11 phonedigit = DIGIT / visual-separator visual-separator = "-" / "." / "(" / ")" pause-character = one-second-pause / wait-for-dial-tone one-second-pause = "p" wait-for-dial-tone = "w" dtmf-digit = "*" / "#" / "A" / "B" / "C" / "D" The URL starts with <telephone-scheme>, which tells the local entity that what follows is a URL that should be parsed as described in this document. After that, the URL contains the phone number of the remote entity. Phone numbers can also contain subaddresses, which are used to identify different remote entities under the same phone number. If a subaddress is present, it is appended to the phone number after ";isub=". Phone numbers can also contain a post-dial sequence. This is what is often used with voice mailboxes and other services that are controlled by dialing numbers from your phone keypad while the call is in progress. The <post-dial> sequence describes what and when the local entity should send to the phone line. Phone numbers can be either "global" or "local". Global numbers are unambiguous everywhere. Local numbers are usable only within a certain area, which is called "context", see section 2.5.2. Local numbers always have an <area-specifier>, which specifies the context in which the number is usable (the same number may have different interpretation in different network areas). The context can be indicated with three different prefixes. A <global-network-prefix> indicates that the number is valid within a numbering area whose global numbers start with <global-network-prefix>. Similarly, <local-network-prefix> means that the number is valid within a Vaha-Sipila Standards Track [Page 5]
RFC 2806 URLs for Telephone Calls April 2000 numbering area whose numbers (or dial strings) start with it. A <private-prefix> is a name of a context. The local entity must have knowledge of this private context to be able to deduce whether it can use the number, see section 2.5.2. Additional information about the phone number's usage can be included by adding the name of the telephony services provider in <service-provider>, see section 2.5.10. The <future-extension> mechanism makes it possible to add new parameters to this URL scheme. See section 2.5.11. The <private-prefix>, <token-char> and <quoted-string> nonterminals may seem a bit complex at first, but they simply describe the set of octets that are legal in those nonterminals. Some octets may have to be escaped, see [RFC2396].

2.3 "fax" URL scheme

The URL syntax is formally described as follows (the definition reuses nonterminals from the above definition). For the basis of this syntax, see [RFC2303] and [RFC2304]. fax-url = fax-scheme ":" fax-subscriber fax-scheme = "fax" fax-subscriber = fax-global-phone / fax-local-phone fax-global-phone = "+" base-phone-number [isdn-subaddress] [t33-subaddress] [post-dial] *(area-specifier / service-provider / future-extension) fax-local-phone = 1*(phonedigit / dtmf-digit / pause-character) [isdn-subaddress] [t33-subaddress] [post-dial] area-specifier *(area-specifier / service-provider / future-extension) t33-subaddress = ";tsub=" 1*phonedigit The fax: URL is very similar to the tel: URL. The main difference is that in addition to ISDN subaddresses, telefaxes also have an another type of subaddress, see section 2.5.8.

2.4 "modem" URL scheme

The URL syntax is formally described as follows (the definition reuses nonterminals from the above definitions). For the basis of this syntax, see [RFC2303]. Vaha-Sipila Standards Track [Page 6]
RFC 2806 URLs for Telephone Calls April 2000 modem-url = modem-scheme ":" remote-host modem-scheme = "modem" remote-host = telephone-subscriber *(modem-params / recommended-params) modem-params = ";type=" data-capabilities recommended-params = ";rec=" data-capabilities data-capabilities = accepted-modem ["?" data-bits parity stop-bits] accepted-modem = "V21" / "V22" / "V22b" / "V23" / "V26t" / "V32" / "V32b" / "V34" / "V90" / "V110" / "V120" / "B103" / "B212" / "X75" / "vnd." vendor-name "." modem-type data-bits = "7" / "8" parity = "n" / "e" / "o" / "m" / "s" stop-bits = "1" / "2" vendor-name = 1*(ALPHA / DIGIT / "-" / "+") modem-type = 1*(ALPHA / DIGIT / "-" / "+") The modem: URL scheme is also very similar to both the tel: and fax: schemes, but it adds the description of the capabilities of the remote entity. Minimum required compliance is listed in <modem- params> and recommended compliance is listed in <recommended-params>. For details, see section 2.5.9.

2.5 Parsing telephone, fax and modem URLs

2.5.1 Call type

The type of call is specified by the scheme specifier. "Tel" means that a voice call is opened. "Fax" indicates that the call should be a facsimile (telefax) call. "Modem" means that it should be a data call. Not all networks differentiate between the types of call; in this case, the scheme specifier indicates the telecommunications equipment type to use.

2.5.2 Phone numbers and their scope

<telephone-subscriber> and <fax-subscriber> indicate the phone number to be dialed. The phone number can be written in either international or local notation. All phone numbers SHOULD always be written in the international form if there is no good reason to use the local form. Not all numbers are valid within all numbering areas. The <area- specifier> parameter, which is mandatory for local numbers, is used to indicate the locale within which this number is valid, or to qualify the phone number so that it may be used unambiguously. The Vaha-Sipila Standards Track [Page 7]
RFC 2806 URLs for Telephone Calls April 2000 <area-specifier> can take three forms: <global-network-prefix>, <local-network-prefix> or <private-prefix>. These are used to describe the validity area of the phone number either in global numbering plan, local numbering plan, or in a private numbering plan, respectively. If <area-specifier> is present, the local entity MUST NOT attempt to call out using the phone number if it cannot originate the call within the specified locale. If a <local-phone-number> is used, an <area-specifier> MUST be included as well. There can be multiple instances of <area-specifier>. In this case, the number is valid in all of the given numbering areas. The global prefix form is intended to act as the outermost context for a phone number, so it will start with a "+", followed by some part of an E.164 number. It also specifies the region in which the phone number is valid. For example, if <global-network-prefix> is "+358", the given number is valid only within Finland (country code 358) - even if it is a <global-phone-number>. The local prefix form is intended to act as an intermediate context in those situations where the outermost context for a phone number is given by another means. One example of use is where the local entity is known to originate calls only within the North American Number Plan Area, so an "outermost" phone context can be assumed. The local context could, for example, be used to indicate the area code within which an associated phone number is situated. Thus "tel:456- 7890;phone-context=213" would suffice to deliver a call to the telephone number "+1-213-456-7890". Note that the version including the <phone-context> implies further that the call can only be originated within the "area code 213" region. The <private-prefix> form is intended for use in those situations where the context cannot be expressed with a start of a global phone number or a dialing string. The <private-prefix> is actually a name of a private context. The creator of the URL and the local entity have been configured to recognize this name, and as such they can interpret the number and know how they can utilize the number. For example, a private network numbering plan may be indicated by the name "X-COMPANY-NET", but the private dialling plan from the locales of the sender of the telephony URL and the local entity are different. The syntax of these tokens will be left for future specification. The ABNF above specifies the accepted characters that can be a part of <private-prefix>. Vaha-Sipila Standards Track [Page 8]
RFC 2806 URLs for Telephone Calls April 2000 Unless the sender is absolutely sure that they share the same private network access digit string with the local entity, then they MUST NOT use a dialling plan number (a local phone number, or one qualified by a local context), as the result may be incorrect. Instead, they SHOULD use a global number, or if that is not possible, a private context as the last resort. If the local entity does not support dialling into the private network indicated by that context, then the request MUST be rejected. If it does, then it will use the access digit string appropriate for its locale. Note that the use of <area-specifier> is orthogonal to use of the telephony service provider parameter (see 2.5.10); it qualifies the phone number, whilst the <service-provider> parameter indicates the carrier to be used for the call attempt. For example, a large company may have private network interconnections between its sites, as well as connections to the Global Switched Telephone Network. A phone number may be given in "public network" form, but with a <service-provider> indicating that the call should be carried over the corporate network. Conversely, it would be possible to represent a phone number in private network form, with a private context to indicate this, but indicate a public telephony service provider. This would request that the user agent convert the private network number plan address into a form that can be carried using the selected service provider. Any telephone number MUST contain at least one <phonedigit> or <dtmf-digit>, that is, subscriber numbers consisting only of pause characters are not allowed. International numbers MUST begin with the "+" character. Local numbers MUST NOT contain that character. International numbers MUST be written with the country (CC) and national (NSN) numbers as specified in [E.123] and [E.164]. International numbers have the property of being totally unambiguous everywhere in the world if the local entity is properly configured. Local numbers MAY be used if the number only works from inside a certain geographical area or a network. Note that some numbers may work from several networks but not from the whole world - these SHOULD be written in international form, with a set of <area- specifier> tags and optional <service-provider> parameters. URLs containing local phone numbers should only appear in an environment where all local entities can get the call successfully set up by passing the number to the dialing entity "as is". An example could be a company intranet, where all local entities are located under a the same private telephone exchange. If local phone numbers are used, Vaha-Sipila Standards Track [Page 9]
RFC 2806 URLs for Telephone Calls April 2000 the document in which they are present SHOULD contain an indication of the context in which they are intended to be used, and an appropriate <area-specifier> SHOULD be present in the URL. In some regions, it is popular to write phone numbers using alphabetic characters which correspond to certain numbers on the telephone keypad. Letters in <dtmf-digit> characters do not have anything to do with this, nor is this method supported by these URL schemes. It should also be noted that implementations MUST NOT assume that telephone numbers have a maximum, minimum or fixed length, or that they would always begin with a certain number. Implementors are encouraged to familiarize themselves with the international standards.

2.5.3 Separators in phone numbers

All <visual-separator> characters MUST be ignored by the local entity when using the URL. These characters are present only to aid readability: they MUST NOT have any other meaning. Note that although [E.123] recommends the use of space (SP) characters as the separators in printed telephone numbers, spaces MUST NOT be used in phone numbers in URLs as the space character cannot be used in URLs without escaping it.

2.5.4 Converting the number to the local numbering scheme

After the telephone number has been extracted, it can be converted to the local dialing convention. (For example, the "+" character might be replaced by the international call prefix, or the international and trunk prefixes might be removed to place a local call.) Numbers that have been specified using <local-phone> or <fax-local-phone> MUST be used by the local entity "as is", without any conversions, unless the local entity decides to utilize the information in an optional <service-provider> parameter.

2.5.5 Sending post-dial sequence after call setup

The number may contain a <post-dial> sequence, which MUST be dialled using Dual Tone Multifrequency (DTMF) in-band signalling or pulse dialing after the call setup is complete. If the user agent does not support DTMF or pulse dialing after the call has been set up, <post- dial> MUST be ignored. In that case, the user SHOULD be notified. Vaha-Sipila Standards Track [Page 10]
RFC 2806 URLs for Telephone Calls April 2000

2.5.6 Pauses in dialing and post-dial sequence

A local phone number or a post-dial sequence may contain <pause- character> characters which indicate a pause while dialing ("p"), or a wait for dial tone ("w"). Local entities MAY support this method of dialing, and the final interpretation of these characters is left to the local entity. It is RECOMMENDED that the length of each pause is about one second. If it is not supported, local entities MUST ignore everything in the dial string after the first <pause-character> and the user SHOULD be notified. The user or the local entity MAY opt not to place a call if this feature is not supported and these characters are present in the URL. Any <dtmf-digit> characters and all dial string characters after the first <pause-character> or <dtmf-digit> SHOULD be sent to line using DTMF (Dual Tone Multifrequency) in-band signaling, even if dialing is done using direct network signaling (a digital subscriber loop or a mobile phone). If the local infrastructure does not support DTMF codes, the local entity MAY opt to use pulse dialing. However, it should be noted that certain services which are controlled using DTMF tones cannot be controlled with pulse dialing. If pulse dialing is used, the user SHOULD be notified.

2.5.7 ISDN subaddresses

A phone number MAY also contain an <isdn-subaddress> which indicates an ISDN subaddress. The local entity SHOULD support ISDN subaddresses. These addresses are sent to the network by using a method available to the local entity (typically, ISDN subscribers send the address with the call setup signalling). If ISDN subaddressing is not supported by the caller, <isdn-subaddress> MUST be ignored and the user SHOULD be notified. The user or the local entity MAY opt not to place a call if this feature is not supported.

2.5.8 T.33 subaddresses

A fax number MAY also contain a <t33-subaddress>, which indicates the start of a T.33 subaddress [T.33]. Local entities SHOULD support this. Otherwise <t33-subaddress> MUST be ignored and the user SHOULD be notified. The user or the local entity MAY opt not to place a call if this feature is not supported. Vaha-Sipila Standards Track [Page 11]
RFC 2806 URLs for Telephone Calls April 2000

2.5.9 Data call parameters

<modem-params> indicate the minimum compliance required from the local entity to be able to connect to the remote entity. The minimum compliance is defined as being equal to or a superset of the capabilities of the listed modem type. There can be several <modem- param> parameters, in which case compliance to any one of them will be accepted. <recommended-params> indicates the recommended compliance required from the local entity. This is typically the fastest and/or the most reliable modem type supported by the modem pool. The local entity can use this information to select the best number from a group of modem URLs. There can be several recommended modem types, which are equally desirable from the modem pool's point of view. <recommended-params> MAY NOT conflict with <modem-params>. If they do, the local entity MUST ignore the <recommended-params>. The local entity MUST call out using compatible hardware, or request that the network provides such a service. For example, if the local entity only has access to a V.22bis modem and the URL indicates that the minimum acceptable connection is V.32bis, the local entity MUST NOT try to connect to the remote host since V.22bis is a subset of V.32bis. However, if the URL lists V.32 as the minimum acceptable connection, the local entity can use V.32bis to create a connection since V.32bis is a superset of V.32. This feature is present because modem pools often have separate numbers for slow modems and fast modems, or have different numbers for analog and ISDN connections, or may use proprietary modems that are incompatible with standards. It is somewhat analogous to the connection type specifier (typecode) in FTP URLs [RFC1738]: it provides the local entity with information that can not be deduced from the scheme specifier, but is helpful for successful operation. This also means that the number of data and stop bits and parity MUST be set according to the information given in the URL, or to default values given in this document, if the information is not present. The capability tokens are listed below. If capabilities suggest that it is impossible to create a connection, the connection MUST NOT be created. If new modem types are standardized by ITU-T, this list can be extended with those capability tokens. Tokens are formed by taking the number of the standard and joining together the first letter (for example, "V"), number (for example, 22) and the first letter of the postfix (for example "bis" would become "b"). Vaha-Sipila Standards Track [Page 12]
RFC 2806 URLs for Telephone Calls April 2000 Proprietary modem types MUST be specified using the 'vendor naming tree', which takes the form "vnd.x.y", in which "x" is the name of the entity from which the specifications for the modem type can be acquired and "y" is the type or model of the modem. Vendor names MUST share the same name space with vendor names used in MIME types [RFC2048]. Submitting the modem types to ietf-types list for review is strongly recommended. New capabilities MUST always be documented in an RFC, and they MUST refer to this document or a newer version of it. The documentation SHOULD also list the existing modem types with which the newly defined modem type is compatible with. Capability Explanation V21 ITU-T V.21 V22 ITU-T V.22 V22b ITU-T V.22bis V23 ITU-T V.23 V26t ITU-T V.26ter V32 ITU-T V.32 V32b ITU-T V.32bis V34 ITU-T V.34 V90 ITU-T V.90 V110 ITU-T V.110 V120 ITU-T V.120 X75 ITU-T X.75 B103 Bell 103 B212 Bell 212 Data bits: "8" or "7" The number of data bits. If not specified, defaults to "8". Parity: "n", "e", "o", Parity. None, even, odd, mark or "m", "s" space parity, respectively. If not specified, defaults to "n". Stop bits: "1" or "2" The number of stop bits. If not specified, defaults to "1".

2.5.10 Telephony service provider identification

It is possible to indicate the identity of the telephony service provider for the given phone number. <service-provider> MAY be used by the user-agent to place the call using this network, to enhance the user interface, for billing estimates or to otherwise optimize its functionality. It MAY also be ignored by the user-agent. <service-provider> consists of a fully qualified Internet domain name of the telephony service provider, for example ";tsp=terrifictelecom.com". The syntax of the domain name follows Internet domain name rules and is defined in [RFC1035]. Vaha-Sipila Standards Track [Page 13]
RFC 2806 URLs for Telephone Calls April 2000

2.5.11 Additional parameters

In addition to T.33 and ISDN subaddresses, modem types and area specifiers, future extensions to this URL scheme may add other additional parameters (<future-extension> in the BNF) to these URLs. These parameters are added to the URL after a semicolon (";"). Implementations MUST be prepared to handle additional and/or unknown parameters gracefully. Implementations MUST NOT use the URL if it contains unknown parameters, as they may be vital for the correct interpretation of the URL. Instead, the implementation SHOULD report an error. For example, <future-extension> 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. Whenever a <future-extension> is used in an open environment, its syntax and usage MUST be properly documented in an RFC. <future-extension> nonterminal a rephrased version of, and compatible with the <other-param> as defined in [RFC2543] (which actually borrows BNF from an earlier version of this specification).

2.6 Examples of Use

tel:+358-555-1234567 This URL points to a phone number in Finland capable of receiving voice calls. The hyphens are included to make the number more human- readable: country and area codes have been separated from the subscriber number. fax:+358.555.1234567 The above URL describes a phone number which can receive fax calls. It uses dots instead of hyphens as separators, but they have no effect on the functionality. modem:+3585551234567;type=v32b?7e1;type=v110 This phone number belongs to an entity which is able to receive data calls. The local entity may opt to use either a ITU-T V.32bis modem (or a faster one, which is compatible with V.32bis), using settings of 7 data bits, even parity and one stop bit, or an ISDN connection using ITU-T V.110 protocol. Vaha-Sipila Standards Track [Page 14]
RFC 2806 URLs for Telephone Calls April 2000 tel:+358-555-1234567;postd=pp22 The above URL instructs the local entity to place a voice call to +358-555-1234567, then wait for an implementation-dependent time (for example, two seconds) and emit two DTMF dialing tones "2" on the line (for example, to choose a particular extension number, or to invoke a particular service). tel:0w003585551234567;phone-context=+3585551234 This URL places a voice call to the given number. The number format is intended for local use: the first zero opens an outside line, the "w" character waits for a second dial tone, and the number already has the international access code appended to it ("00"). This kind of phone number MUST NOT be used in an environment where all users of this URL might not be able to successfully dial out by using this number directly. However, this might be appropriate for pages in a company intranet. The <area-specifier> which is present hints that the number is usable only in an environment where the local entity's phone number starts with the given string (perhaps singling out a company-wide block of telephone numbers). tel:+1234567890;phone-context=+1234;vnd.company.option=foo The URL describes a phone number which, even if it is written in its international form, is only usable within the numbering area where phone numbers start with +1234. There is also a proprietary extension "vnd.company.option", which has the value "foo". The meaning of this extension is application-specific. Note that the order of these parameters (phone-context and vnd.company.option) is irrelevant.

2.7 Rationale behind the syntax

2.7.1 Why distinguish between call types?

URLs locate resources, which in this case is some telecommunications equipment at a given phone number. However, it is not necessarily enough to know the subscriber number in order to successfully communicate with that equipment. Digital phone networks distinguish between voice, fax and data calls (and possibly other types of calls, not discussed in this specification). To be able to successfully connect to, say, a fax machine, the caller may have to specify that a fax call is being made. Otherwise the call might be routed to the voice number of the subscriber. In this sense, the call type is an integral part of the 'location' of the target resource. Vaha-Sipila Standards Track [Page 15]
RFC 2806 URLs for Telephone Calls April 2000 The reason to have the call type in the scheme specifier is to make the URL simple to remember and use. Making it a parameter, much like the way modem parameters are handled now, will substantially reduce the human readability of this URL.

2.7.2 Why "tel" is "tel"?

There has been discussion on whether the scheme name "tel" is appropriate. To summarize, these are the points made against the other proposals. callto URL schemes locate a resource and do not specify an action to be taken. telephone Too long. Also, "tel" considered to be a more international form. phone Was countered on the basis that "tel" is more internationally acceptable.

2.7.3 Why to use E.164-style numbering?

E.164 refers to international telephone numbers, and the string of digits after the country code is usually a national matter. In any case, phone numbers are usually written as a simple string of numbers everywhere. Because of this, the syntax in this specification is intuitively clear to most people. This is the usual way to write phone numbers in business cards, advertisements, telephone books and so on. It should be noted that phone numbers may have 'hierarchical' characteristics, so that one could build a 'forest' of phone numbers with country codes as roots, area codes as branches and subscriber numbers as leaves. However, this is not always the case. Not all areas have area codes; some areas may have different area codes depending on how one wants to route the call; some numbers must always be dialled "as is", without prepending area or country codes (notably emergency numbers); and area codes can and do change. Usually, if something has a hierarchical structure, the URL syntax should reflect that fact. These URLs are an exception. Also, when writing the phone number in the form described in this specification, the writer does not need to know which part of the number is the country code and which part is the area code. If a hierarchical URL would be used (with a "/" character separating the parts of the phone numbers), the writer of the URL would have to know which parts are which. Vaha-Sipila Standards Track [Page 16]
RFC 2806 URLs for Telephone Calls April 2000 Finally, when phone numbers are written in the international form as specified here, they are unambiguous and can always be converted to the local dialing convention, given that the user agent has the knowledge of the local country and area codes.

2.7.4 Not everyone has the same equipment as you

There are several ways for the subscriber to dial a phone number: - By pulse dialing. Typically old telephone exchanges. Usually this dialing method has only to be used to set up the call; after connecting to the remote entity, <post-dial> can be sent to the line using DTMF, because it will typically be processed by the remote entity, not the telephone network. - By DTMF. These are the 'beeps' that you hear when you dial on most phones. - By direct network signalling. ISDN subscribers and mobile phone users usually have this. There is no dial tone (or if there is, it is generated locally by the equipment), and the number of the called party is communicated to the telephone network using some network signalling method. After setting up the call, <post-dial> sequences are usually sent using DTMF codes.

2.7.5 Do not confuse numbers with how they are dialled

As an example, +123456789 will be dialled in many countries as 00123456789, where the leading "00" is a prefix for international calls. However, if a URL contains a local phone number 00123456789, the user-agent MUST NOT assume that this number is equal to a global phone number +123456789. If a user-agent received a telephony URL with a local number in it, 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, anyone sending a telephony URL MUST take into consideration that the recipient may have insufficient information about the phone number's context.

3. Comments on usage

These are examples of the recommended usage of this URL in HTML documents. First of all, the number SHOULD be visible to the end user, if it is conceivable that the user might not have a local entity which is able to use these URLs. Telephone: <a href="tel:+3585551234567">+358-555-1234567</a> Vaha-Sipila Standards Track [Page 17]
RFC 2806 URLs for Telephone Calls April 2000 Second, on a public HTML page, the telephone number in the URL SHOULD always be in the international form, even if the text of the link uses some local format. Telephone: <a href="tel:+3585551234567">(0555) 1234567</a> or even For more info, call <a href="tel:+15554383785965">1-555-IETF-RULZ- OK</a>. Moreover, if the number is a <local-phone-number>, and the scope of the number is not clear from the context in which the URL is displayed, a human-readable explanation SHOULD be included. For customer service, dial <a href="tel:1234;phone- context=+358555">1234</a> (only from Terrific Telecom mobile phones).

4. References

[RFC1035] Mockapetris, P., "Domain Names - Implementation and Specification", STD 13, RFC 1035, November 1987. [RFC1738] Berners-Lee, T., et al., "Uniform Resource Locators (URL)", RFC 1738, December 1994. [RFC1866] Berners-Lee, T. and D. Connolly, "Hypertext Markup Language - 2.0", RFC 1866, November 1995. [RFC2048] Freed, N., Klensin, J. and J. Postel, "Multipurpose Internet Mail Extensions (MIME) Part Four: Registration Procedures", RFC 2048, November 1996. [RFC2119] Bradner, S., "Key Words for Use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2234] Crocker, D. and P. Overall, "Augmented BNF for Syntax Specifications: ABNF", RFC 2234, November 1997. [RFC2303] Allocchio, C., "Minimal PSTN Address Format in Internet Mail", RFC 2303, March 1998. [RFC2304] Allocchio, C., "Minimal FAX Address Format in Internet Mail", RFC 2304, March 1998. Vaha-Sipila Standards Track [Page 18]
RFC 2806 URLs for Telephone Calls April 2000 [RFC2396] Berners-Lee, T., R. Fielding and L. Manister, "Uniform Resource Identifiers (URI): Generic Syntax", RFC 2396, August 1998. [RFC2543] Handley, M., Schulzrinne, H., Schooler, E. and J. Rosenberg, "SIP: Session Initiation Protocol", RFC 2543, March 1999. [E.123] ITU-T Recommendation E.123: Telephone Network and ISDN Operation, Numbering, Routing and Mobile Service: Notation for National and International Telephone Numbers. 1993. [E.164] ITU-T Recommendation E.164/I.331 (05/97): The International Public Telecommunication Numbering Plan. 1997. [T.33] ITU-T Recommendation T.33: Facsimile Routing Utilizing the Subaddress. 1996.

5. Security Considerations

It should be noted that the local entity SHOULD NOT call out without the knowledge of the user because of associated risks, which include - call costs (including long calls, long distance calls, international calls and premium rate calls, or calls which do not terminate due to <post-dial> sequences that have been left out by the local entity) - wrong numbers inserted on web pages by malicious users, or sent via e-mail, perhaps in direct advertising - making the user's phone line unavailable (off-hook) for a malicious purpose - opening a data call to a remote host, thus possibly opening a back door to the user's computer - revealing the user's (possibly unlisted) phone number to the remote host in the caller identification data, and correlating the local entity's phone number with other information such as the e-mail or IP address - using the same local number in different contexts, in which the number may have a different meaning All of these risks MUST be taken into consideration when designing the local entity. Vaha-Sipila Standards Track [Page 19]
RFC 2806 URLs for Telephone Calls April 2000 The local entity SHOULD have some mechanism that the user can use to filter out unwanted numbers. The local entity SHOULD NOT use rapid redialing of the number if it is busy to avoid the congestion of the (signaling) network. Also, the local entity SHOULD detect if the number is unavailable or if the call is terminated before the dialing string has been completely processed (for example, the call is terminated while waiting for user input) and not try to call again, unless instructed by the user.

6. Acknowledgements

Writing this specification would not have been possible without extensive support from many people. Contributors include numerous people from IETF FAX, PINT, URI and URLREG mailing lists, as well as from World Wide Web Consortium and several companies, plus several individuals. Thanks to all people who offered criticism, corrections and feedback. All phone numbers and company names used in the examples of this specification are fictional. Any similarities to real entities are coincidental.

7. Author's Address

Antti Vaha-Sipila (quoted-printable: Antti V=E4h=E4-Sipil=E4) Nokia Mobile Phones P. O. Box 68 FIN-33721 Tampere Finland EMail: avs@iki.fi antti.vaha-sipila@nokia.com Vaha-Sipila Standards Track [Page 20]
RFC 2806 URLs for Telephone Calls April 2000

8. Full Copyright Statement

Copyright (C) The Internet Society (2000). All Rights Reserved. This document and translations of it may be copied and furnished to others, and derivative works that comment on or otherwise explain it or assist in its implementation 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 copyrights defined in the Internet Standards process must be followed, or as required to translate it into languages other than English. The limited permissions granted above are perpetual and will not be revoked by the Internet Society or its successors or assigns. 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. Acknowledgement Funding for the RFC Editor function is currently provided by the Internet Society. Vaha-Sipila Standards Track [Page 21]