Network Working Group H. Schulzrinne Request for Comments: 5244 Columbia U. Updates: 4733 T. Taylor Category: Standards Track Nortel June 2008
Definition of Events for Channel-Oriented Telephony Signalling
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.
Abstract
This memo updates RFC 4733 to add event codes for telephony signals used for channel-associated signalling when carried in the telephony event RTP payload. It supersedes and adds to the original assignment of event codes for this purpose in Section 3.14 of RFC 2833. As documented in Appendix A of RFC 4733, some of the RFC 2833 events have been deprecated because their specification was ambiguous, erroneous, or redundant. In fact, the degree of change from Section 3.14 of RFC 2833 is such that implementations of the present document will be fully backward compatible with RFC 2833 implementations only in the case of full ABCD-bit signalling. This document expands and improves the coverage of signalling systems compared to RFC 2833.
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Table of Contents 1. Introduction ....................................................2 1.1. Overview ...................................................2 1.2. Terminology ................................................3 2. Event Definitions ...............................................4 2.1. Signalling System No. 5 ....................................6 2.1.1. Signalling System No. 5 Line Signals ................6 2.1.2. Signalling System No. 5 Register Signals ............7 2.2. Signalling System R1 and North American MF .................8 2.2.1. Signalling System R1 Line Signals ...................8 2.2.2. Signalling System R1 Register Signals ...............8 2.3. Signalling System R2 ......................................10 2.3.1. Signalling System R2 Line Signals ..................10 2.3.2. Signalling System R2 Register Signals ..............10 2.4. ABCD Transitional Signalling for Digital Trunks ...........12 2.5. Continuity Tones ..........................................14 2.6. Trunk Unavailable Event ...................................14 2.7. Metering Pulse Event ......................................15 3. Congestion Considerations ......................................15 4. Security Considerations ........................................16 5. IANA Considerations ............................................17 6. Acknowledgements ...............................................20 7. References .....................................................20 7.1. Normative References ......................................20 7.2. Informative References ....................................21
This document extends the set of telephony events defined within the framework of RFC 4733 [4] to include signalling events that can appear on a circuit in the telephone network. Most of these events correspond to signals within one of several channel-associated signalling systems still in use in the PSTN.
Trunks (or circuits) in the PSTN are the media paths between telephone switches. A succession of protocols have been developed using tones and electrical conditions on individual trunks to set up telephone calls using them. The events defined in this document support an application where such PSTN signalling is carried between two gateways without being signalled in the IP network: the "RTP trunk" application.
In the "RTP trunk" application, RTP is used to replace a normal circuit-switched trunk between two nodes. This is particularly of interest in a telephone network that is still mostly circuit-switched. In this case, each end of the RTP trunk encodes
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audio channels into the appropriate encoding, such as G.723.1 [13] or G.729 [14]. However, this encoding process destroys in-band signalling information that is carried using the least-significant bit ("robbed bit signalling") and may also interfere with in-band signalling tones, such as the MF (multi-frequency) digit tones.
In a typical application, the gateways may exchange roles from one call to the next: they must be capable of either sending or receiving each implemented signal in Table 1.
This document defines events related to four different signalling systems. Three of these are based on the exchange of multi-frequency tones. The fourth operates on digital trunks only, and makes use of low-order bits stolen from the encoded media. In addition, this document defines tone events for supporting tasks such as continuity testing of the media path.
Implementors are warned that the descriptions of signalling systems given below are incomplete. They are provided to give context to the related event definitions, but omit many details important to implementation.
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.
In addition to the abbreviations defined below for specific events, this document uses the following abbreviations:
KP Key Pulse
MF Multi-frequency
PSTN Public Switched (circuit) Telephone Network
RTP Real-time Transport Protocol [2]
ST Start
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Table 1 lists all of the events defined in this document. As indicated in Table 8 (Appendix A) of RFC 4733 [4], use of some of the RFC 2833 [11] event codes has been deprecated because their specification was ambiguous, erroneous, or redundant. In fact, the degree of change from Section 3.14 of RFC 2833 is such that implementations of the present document will be fully backward compatible with RFC 2833 implementations only in the case of full ABCD-bit signalling. This document expands and improves the coverage of signalling systems compared to RFC 2833.
Note that the IANA registry for telephony event codes was set up by RFC 4733, not by RFC 2833. Thus, event code assignments originally made in RFC 2833 appear in the registry only if reaffirmed in RFC 4733 or an update to RFC 4733, such as the present document.
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Signalling System No. 5 (SS No. 5) is defined in ITU-T Recommendations Q.140 through Q.180 [5]. It has two systems of signals: "line" signalling to acquire and release the trunk, and "register" signalling to pass digits forward from one switch to the next.
No. 5 line signalling uses tones at two frequencies: 2400 and 2600 Hz. The tones are used singly for most signals, but together for the Clear-forward and Release-guard. (This reduces the chance of an accidental call release due to carried media content duplicating one of the frequencies.) The specific signal indicated by a tone depends on the stage of call set-up at which it is applied.
No events are defined in support of No. 5 line signalling. However, implementations MAY use the AB bit events described in Section 2.4 and shown in Table 1 to propagate SS No. 5 line signals. If they do so, they MUST use the following mappings. These mappings are based on an underlying mapping equating A=0 to presence of 2400 Hz signal and B=0 to presence of 2600 Hz signal in the indicated direction.
o both 2400 and 2600 Hz present: event code 208;
o 2400 Hz present: event code 210;
o 2600 Hz present: event code 209;
o neither signal present: event code 211.
The initial event report for each signal SHOULD be generated as soon as the signal is recognized, and in any case no later than the time of recognition as indicated in ITU-T Recommendation Q.141, Table 1 (i.e., 40 ms for "seizing" and "proceed-to-send", 125 ms for all other signals). The packetization interval following the initial report SHOULD be chosen with considerations of reliable transmission given first priority. Note that the receiver must supply its own volume values for converting these events back to tones. Moreover, the receiver MAY extend the playout of "seizing" until it has received the first report of a KP event (see below), so that it has better control of the interval between ending of the seizing signal and start of KP playout.
The KP has to be sent beginning 80 +/- 20 ms after the SS No. 5 "seizing" signal has stopped.
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No. 5 register signalling uses pairs of tones to convey digits and signals framing them. The tone combinations and corresponding signals are shown in the Table 2. All signals except KP1 and KP2 are sent for a duration of 55 ms. KP1 and KP2 are sent for a duration of 100 ms. Inter-signal pauses are always 55 ms.
The KP signals are used to indicate the start of digit signalling. KP1 indicates a call expected to terminate in a national network served by the switch to which the signalling is being sent. KP2 indicates a call that is expected to transit through the switch to which the signalling is being sent, to another international exchange. The end of digit signalling is indicated by the ST signal. Code 11 or Code 12 following a country code (and possibly another digit) indicates a call to be directed to an operator position in the destination country. A Code 12 may be followed by other digits indicating a particular operator to whom the call is to be directed.
Implementations using the telephone-events payload to carry SS No. 5 register signalling MUST use the following events from Table 1 to convey the register signals shown in Table 2:
o event code 128 to convey Digit 0;
o event codes 129-137 to convey Digits 1 through 9, respectively;
o event code 123 to convey Code 11;
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o event code 124 to convey KP1;
o event code 125 to convey KP2;
o event code 126 to convey ST;
o event code 127 to convey Code 12.
The sending implementation SHOULD send an initial event report for the KP signals as soon as they are recognized, and it MUST send an event report for all of these signals as soon as they have completed.
Signalling System R1 is mainly used in North America, as is the more common variant designated simply as "MF". R1 is defined in ITU-T Recommendations Q.310-Q.332 [6], while MF is defined in [9].
Like SS No. 5, R1/MF has both line and register signals. The line signals (not counting Busy and Reorder) are implemented on analog trunks through the application of a 2600 Hz tone, and on digital trunks by using ABCD signalling. Interpretation of the line signals is state-dependent (as with SS No. 5).
In accordance with Table 1/Q.311, implementations MAY use the A bit events described in Section 2.4 and shown in Table 1 to propagate R1 line signals. If they do so, they MUST use the following mappings. These mappings are based on an underlying mapping equating A=0 to the presence of a 2600 Hz signal in the indicated direction and A=1 to the absence of that signal.
R1 has a signal capacity of 15 codes for forward inter-register signals but no backward inter-register signals. Each code or digit is transmitted by a tone pair from a set of 6 frequencies. The R1 register signals consist of KP, ST, and the digits "0" through "9". The frequencies allotted to the signals are shown in Table 3. Note
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that these frequencies are the same as those allotted to the similarly named SS No. 5 register signals, except that KP uses the frequency combination corresponding to KP1 in SS No. 5. Table 3 also shows additional signals used in North American practice: KP', KP2P, KP3P, STP or ST', ST2P, and ST3P [9].
Implementations using the telephone-events payload to carry North American R1 register signalling MUST use the following events from Table 1 to convey the register signals shown in Table 3:
o event code 128 to convey Digit 0;
o event codes 129-137 to convey Digits 1 through 9, respectively;
o event code 123 to convey KP3P or ST3P;
o event code 124 to convey KP;
o event code 125 to convey KP2P or ST2P;
o event code 126 to convey ST;
o event code 127 to convey KP' or STP.
As with the original telephony signals, the receiver interprets codes 123, 125, and 127 as KPx or STx signals based on their position in the signalling sequence.
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Unlike SS No. 5, R1 allows a large tolerance for the time of onset of register signalling following the recognition of start-dialling line signal. This means that sending implementations MAY wait to send a KP event report until the KP has completed.
The International Signalling System R2 is described in ITU-T Recommendations Q.400-Q.490 [7], but there are many national variants. R2 line signals are continuous, out-of-band, link by link, and channel associated. R2 (inter)register signals are multi- frequency, compelled, in-band, end-to-end, and also channel associated.
R2 line signals may be analog, one-bit digital using the A bit in the 16th channel, or digital using both A and B bits. Implementations MAY use the A bit or AB bit events described in Section 2.4 and shown in Table 1 to propagate these signals. If they do so, they MUST use the following mappings.
1. For the analog R2 line signals shown in Table 1 of ITU-T Recommendation Q.411, implementations MUST map as follows. This mapping is based on an underlying mapping of A bit = 0 when tone is present.
* event code 206 (Table 1) is used to indicate the Q.411 "tone- on" condition;
* event code 207 (Table 1), is used to indicate the Q.411 "tone- off" condition.
2. The digital R2 line signals, as described by ITU-T Recommendation Q.421, are carried in two bits, A and B. The mapping between A and B bit values and event codes SHALL be the same in both directions and SHALL follow the principles for A and B bit mapping specified in Section 2.4.
In R2 signalling, the signalling sequence is initiated from the outgoing exchange by sending a line "seizing" signal. After the line "seizing" signal (and "seizing acknowledgment" signal in R2D), the signalling sequence continues using MF register signals. ITU-T Recommendation Q.441 classifies the forward MF register signals
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(upper frequencies) into Groups I and II, the backward MF register signals (lower frequencies) into Groups A and B. These groups are significant with respect both to what sort of information they convey and where they can occur in the signalling sequence.
The tones used in R2 register signalling are combinations of two out of six frequencies. National versions may be reduced to 10 signals (two out of five frequencies) or 6 signals (two out of four frequencies).
R2 register signalling is a compelled tone signalling protocol, meaning that one tone is played until an "acknowledgment or directive for the next tone" is received that indicates that the original tone should cease. A R2 forward register signal is acknowledged by a backward signal. A backward signal is acknowledged by the end of the forward signal. In exceptional circumstances specified in ITU-T Rec. Q.442, the downstream entity may send backward signals autonomously rather than in response to specific forward signals.
In R2 signalling, the signalling sequence is initiated from the outgoing exchange by sending a forward Group I signal. The first forward signal is typically the first digit of the called number. The incoming exchange typically replies with a backward Group A-1 indicating to the outgoing exchange to send the next digit of the called number.
The tones have meaning; however, the meaning varies depending on where the tone occurs in the signalling. The meaning may also depend on the country. Thus, to avoid an unmanageable number of events, this document simply provides means to indicate the 15 forward and 15 backward MF R2 tones (i.e., using event codes 176-190 and 191-205, respectively, as shown in Table 1). The frequency pairs for these tones are shown in Table 4 and Table 5.
Note that a naive strategy for onward relay of R2 inter-register signals may result in unacceptably long call setup times and timeouts when the call passes through several exchanges as well as a gateway before terminating. Several strategies are available for speeding up the transfer of signalling information across a given relay point. In the worst case, the relay point has to act as an exchange, terminating the signalling on one side and reoriginating the call on the other.
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2.4. ABCD Transitional Signalling for Digital Trunks
ABCD is a 4-bit signalling system used by digital trunks, where A, B, C, and D are the designations of the individual bits. Signalling may be 16-state (all four bits used), 4-state (A and B bits used), or 2-state (A-bit only used). ABCD signalling events are all mutually exclusive states. The most recent state transition determines the current state.
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When using Extended Super Frame (ESF) T1 framing, signalling information is sent as robbed bits in frames 6, 12, 18, and 24. A D4 superframe only transmits 4-state signalling with A and B bits. On the Conference of European Postal and Telecommunications (CEPT) E1 frame, all signalling is carried in timeslot 16, and two channels of 16-state (ABCD) signalling are sent per frame. ITU-T Recommendation G.704 [10] gives the details of ABCD bit placement within the various framing arrangements.
The meaning of ABCD signals varies with the application. One example of a specification of ABCD signalling codes is T1.403.02 [16], which reflects North American practice for "loop" signalling as opposed to the trunk signalling discussed in previous sections.
Since ABCD information is a state rather than a changing signal, implementations SHOULD use the following triple-redundancy mechanism, similar to the one specified in ITU-T Rec. I.366.2 [15], Annex L. At the time of a transition, the same ABCD information is sent 3 times at an interval of 5 ms. If another transition occurs during this time, then this continues. After a period of no change, the ABCD information is sent every 5 seconds.
As shown in Table 1, the 16 possible states are represented by event codes 144 to 159, respectively. Implementations using these event codes MUST map them to and from the ABCD information based on the following principles:
1. State numbers are derived from the used subset of ABCD bits by treating them as a single binary number, where the A bit is the high-order bit.
2. State numbers map to event codes by order of increasing value (i.e., state number 0 maps to event code 144, ..., state number 15 maps to event code 159).
If only the A and B bits are being used, then the mapping to event codes shall be as follows:
o A=0, B=0 maps to event code 208;
o A=0, B=1 maps to event code 209;
o A=1, B=0 maps to event code 210;
o A=1, B=1 maps to event code 211;
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Finally, if only the A bit is used,
o A = 0 maps to event code 206;
o A = 1 maps to event code 207;
Separate event codes are assigned to A-bit and AB-bit signalling because, as indicated in Rec. G.704 [10], when the B, C, and D bits are unused, their default values differ between transmission systems. By specifying codes for only the used bits, this memo allows the receiving gateway to fill in the remaining bits according to local configuration.
Continuity tones are used for testing circuit continuity during call setup. Two basic procedures are used. In international practice, clause 7 of ITU-T Recommendation Q.724 [8] describes a procedure applicable to four-wire trunk circuits, where a single 2000 +/- 20 Hz check-tone is transmitted from the initiating telephone switch. The remote switch sets up a loopback, and the continuity check passes if the sending switch can detect the tone on the return path. Clause 8 of Q.724 describes the procedure for two-wire trunk circuits. The two-wire procedure involves two tones: a 2000 Hz tone sent in the forward direction and a 1780 +/- 20 Hz tone sent in response.
Note that implementations often send a slightly different check-tone, e.g., 2010 Hz, because of undesirable aliasing properties of 2000 Hz.
If implementations use the telephone-events payload type to propagate continuity check-tones, they MUST map these tones to event codes as follows:
o For four-wire continuity testing, the 2000 Hz check-tone is mapped to event code 121.
o For two-wire continuity testing, the initial 2000 Hz check-tone Hz tone is mapped to event code 121. The 1780 Hz continuity verify-tone is mapped to event code 122.
This event indicates that the trunk is unavailable for service. The length of the downtime is indicated in the duration field. The duration field is set to a value that allows adequate granularity in describing downtime. A value of 1 second is RECOMMENDED. When the
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trunk becomes unavailable, this event is sent with the same timestamp three times at an interval of 20 ms. If the trunk persists in the unavailable state at the end of the indicated duration, then the event is retransmitted, preferably with the same redundancy scheme.
Unavailability of the trunk might result from a failure or an administrative action. This event is used in a stateless manner to synchronize trunk unavailability between equipment connected through provisioned RTP trunks. It avoids the unnecessary consumption of bandwidth in sending a continuous stream of RTP packets with a fixed payload for the duration of the downtime, as would be required in certain E1-based applications. In T1-based applications, trunk conditioning via the ABCD transitional events can be used instead.
The metering pulse event may be used to transmit meter pulsing for billing purposes. For background information, one possible reference is http://www.seg.co.uk/telecomm/automat3.htm. Since the metering pulse is a discrete event, each metering pulse event report MUST have both the 'M' and 'E' bits set. Meter pulsing is normally transmitted by out-of-band means while conversation is in progress. Senders MUST therefore be prepared to transmit both the telephone-event and audio payload types simultaneously. Metering pulse events MUST be retransmitted as recommended in Section 2.5.1.4 of RFC 4733 [4]. It is RECOMMENDED that the retransmission interval be the lesser of 50 ms and the pulsing rate but no less than audio packetization rate.
The ability to adapt to congestion varies with the signalling system being used and also differs between line and register signals.
With the specific exception of register signalling for S.S. No. 5 and R1/MF, the signals described in this document are fairly tolerant of lengthened durations, should these be necessary. Thus in congested conditions, the sender may adapt by lengthening the reporting interval for the tones concerned. At the receiving end, if a tone is being played out and an under-run occurs due to delayed or lost packets, it is best to continue playing the tone until the next packet arrives. Interrupting a tone prematurely, with or without resumption, can cause the call setup attempt to fail, whereas extended playout just increases the call setup time.
Register signalling for S.S. No. 5 and R1/MF is subject to time constraints. Both the tone signals and the silent periods between them have specified durations and tolerances of the order of 5 to 10 ms. The durations of the individual tones are of the order of two to
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three packetization intervals (55/68 ms, with the initial KP lasting 100 ms). The critical requirement for transmission of the telephony-event payload is that the receiver knows which signal to play out at a given moment. It is less important that the receiver receive timely notification of the end of each tone. Rather, it should play out the sequence with the durations specified by the signalling standard instead of the actual durations reported.
These considerations suggest that as soon as a register signal has been reliably identified, the sender should emit a report of that tone. It should then provide an update within 5 ms for reliability and no more updates until reporting the end of the tone.
Increasing the playout buffer at the receiver during register signalling will increase reliability. This has to be weighed against the implied increase in call setup time.
The events for which event codes are provided in this document relate directly to the setup, billing, and takedown of telephone calls. As such, they are subject, using the terminology of RFC 3552 [12], to threats to both communications and system security. The attacks of concern are:
o confidentiality violations (monitoring of calling and called numbers);
o establishment of unauthorized telephone connections through message insertion;
o hijacking of telephone connections through message insertion or man-in-the-middle modification of messages;
o denial of service to individual telephone calls through message insertion, modification, deletion, or delay.
These attacks can be prevented by the use of appropriate confidentiality, authentication, or integrity protection. If confidentiality, authentication, or integrity protection are needed, then Secure Real-time Transport Protocol (SRTP) [3] SHOULD be used with automated key management.
Additional security considerations are described in RFC 4733 [4].
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This document defines the event codes shown in Table 6. These events are additions to the telephone-event registry established by RFC 4733 [4]. The reference for all of them is the present document.
The complete list of acknowledgements for contribution to the development and revision of RFC 2833 is contained in RFC 4733 [4]. The Editor believes or is aware that the following people contributed specifically to the present document: Flemming Andreasen, Rex Coldren, Bill Foster, Alfred Hoenes, Rajesh Kumar, Aleksandar Lebl, Zarko Markov, Oren Peleg, Moshe Samoha, Adrian Soncodi, and Yaakov Stein. Steve Norreys and Roni Even provided useful review comments.
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[2] Schulzrinne, H., Casner, S., Frederick, R., and V. Jacobson, "RTP: A Transport Protocol for Real-Time Applications", STD 64, RFC 3550, July 2003.
[3] Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, "The Secure Real-time Transport Protocol (SRTP)", RFC 3711, March 2004.
[4] Schulzrinne, H. and T. Taylor, "RTP Payload for DTMF Digits, Telephony Tones, and Telephony Signals", RFC 4733, December 2006.
[5] International Telecommunication Union, "Specifications for signalling system no. 5", ITU-T Recommendation Q.140-Q.180, November 1988.
[6] International Telecommunication Union, "Specifications of Signalling System R1", ITU-T Recommendation Q.310-Q.332, November 1988.
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[7] International Telecommunication Union, "Specifications of Signalling System R2", ITU-T Recommendation Q.400-Q.490, November 1988.
[8] International Telecommunication Union, "Telephone user part signalling procedures", ITU-T Recommendation Q.724, November 1988.
[9] Telcordia Technologies, "LSSGR: signalling for Analog Interfaces", Generic Requirement GR-506, June 1996.
[10] International Telecommunication Union, "Synchronous frame structures used at 1544, 6312, 2048, 8448 and 44 736 kbit/s hierarchical levels", ITU-T Recommendation G.704, October 1998.
[11] Schulzrinne, H. and S. Petrack, "RTP Payload for DTMF Digits, Telephony Tones and Telephony Signals", RFC 2833, May 2000.
[12] Rescorla, E. and B. Korver, "Guidelines for Writing RFC Text on Security Considerations", BCP 72, RFC 3552, July 2003.
[13] International Telecommunication Union, "Speech coders : Dual rate speech coder for multimedia communications transmitting at 5.3 and 6.3 kbit/s", ITU-T Recommendation G.723.1, March 1996.
[14] International Telecommunication Union, "Coding of speech at 8 kbit/s using conjugate-structure algebraic-code-excited linear- prediction (CS-ACELP)", ITU-T Recommendation G.729, March 1996.
[15] International Telecommunication Union, "AAL type 2 service specific convergence sublayer for trunking", ITU-T Recommendation I.366.2, February 1999.
[16] ANSI/T1, "Network and Customer Installation Interfaces -- DS1 Robbed-Bit signalling State Definitions", American National Standard for Telecommunications T1.403.02-1999, May 1999.
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Authors' Addresses
Henning Schulzrinne Columbia U. Dept. of Computer Science Columbia University 1214 Amsterdam Avenue New York, NY 10027 US
EMail: schulzrinne@cs.columbia.edu
Tom Taylor Nortel 1852 Lorraine Ave Ottawa, Ontario K1H 6Z8 CA
EMail: tom.taylor@rogers.com
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