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.rs .\" Troff code generated by TPS Convert from ITU Original Files .\" Not Copyright (~c) 1991 .\" .\" Assumes tbl, eqn, MS macros, and lots of luck. .TA 1c 2c 3c 4c 5c 6c 7c 8c .ds CH .ds CF .EQ delim @@ .EN .nr LL 40.5P .nr ll 40.5P .nr HM 3P .nr FM 6P .nr PO 4P .nr PD 9p .po 4P .rs \v'|.5i' .sp 2P .LP \fB9\fR \fBConformance to this standard\fR .sp 1P .RT .PP 9.1 A system claiming conformance to this Recommendation shall exhibit external behaviour consistent with having implemented an SPM for the Kernel functional unit together with either or both of the Half\(hyduplex and the Duplex functional units. .sp 9p .RT .PP 9.2 The system may exhibit external behaviour consistent with containing an implementation of any other functional unit provided that: .LP a) if the Capability Data functional unit is implemented, the Activity Management functional unit shall also be implemented; and .LP b) if the Exceptions functional unit is implemented, the Half\(hyduplex functional unit shall also be implemented. .PP 9.3 For all protocol versions which are claimed to be implemented, the system shall be capable of: .LP a) initiating a session connection (by sending a CONNECT SPDU) or responding to a CONNECT SPDU (according to the procedures specified in section\ 7), or both; .LP b) following all the remaining procedures in the Kernel functional unit; and .LP c) following all the procedures for each functional unit that the system claims to implement, .LP where following the procedures specified in\ b) and\ c) shall mean: .LP d) accepting all correct sequences of SPDUs received from peer equipment, and responding with correct SPDU sequences, for the defined states of a session connection; .LP e) responding correctly to all incorrect sequences of SPDUs received for a defined state of a session connection. .PP 9.4 Claims of conformance shall state: .LP a) which functional units are implemented; .LP b) whether or not extended concatenation is implemented; .LP c) whether or not segmenting is implemented and, if segmenting is implemented, the maximum size of TSDU which the system is capable of handling; .LP d) whether or not the use of transport expedited service is implemented; .LP e) which protocol versions are implemented. .PP 9.5 The implementor shall provide a Protocol Implementation Conformance Statement (PICS). .PP \fINote\fR \ \(em\ In particular any limit imposed by an implementation on the number of octets of SS\(hyuser data which can be passed in a single session primitive shall be stated in the\ PICS. .ce 1000 ANNEX\ A .ce 0 .ce 1000 (to Recommendation X.225) .sp 9p .RT .ce 0 .ce 1000 \fBState tables\fR .sp 1P .RT .ce 0 .LP A.1 \fIGeneral\fR .sp 1P .RT .PP This Annex describes the session protocol in terms of state tables. The state tables show the state of a session connection, the events that occur in the protocol, the actions taken and the result state. .PP These state tables do not constitute a formal definition of the session protocol; they are included to provide a more precise specification of the elements of procedure described in \(sc\ 7. .PP Table A\(hy1/X.225 specifies the abbreviated name, category and name of each incoming event. The categories are SS\(hyuser event, TS\(hyprovider event, timer event and valid SPDU event. .PP Table\ A\(hy2/X.225 specifies the abbreviated name and name of each state. .PP Table\ A\(hy3/X.225 specifies the abbreviated name, category and name of each outgoing event. The categories are SS\(hyprovider event, TS\(hyuser event and SPDU event. .PP Table\ A\(hy4/X.225 summarizes the operations on the variables (VA), V(M), V(R) and\ Vsc. .PP Table\ A\(hy5/X.225 specifies the specific actions. .PP Table\ A\(hy6/X.225 specifies the predicates. .PP Tables\ A\(hy7/X.225 to A\(hy15/X.225 specify the state tables. .bp .RT .sp 2P .LP A.2 \fINotation for state tables\fR .sp 1P .RT .PP A.2.1 Incoming events, states and outgoing events are represented by their abbreviated names. .sp 9p .RT .PP A.2.2 Specific actions are represented by the notation [\fIn\fR ], where \fIn\fR \| is the number of the specific action in Table\ A\(hy5/X.225. .PP A.2.3 Notes are represented by the notation (\fIn\fR ), where \fIn\fR \| is the number of the note at the foot of Table\ A\(hy6/X.225. .PP A.2.4 Predicates are represented by the notation p\fIn\fR , where \fIn\fR \| is the number of the predicate in Table\ A\(hy6/X.225. .PP A.2.5 Boolean operators are represented by the following notation: .LP & AND .LP \*\|i NOT .LP OR OR .sp 2P .LP A.3 \fIConventions for entries in state tables\fR .sp 1P .RT .PP A.3.1 The intersection of each state and incoming event which is invalid is left blank. .sp 9p .RT .PP A.3.2 The intersection of each state and incoming event which is valid contains entries which are either: .LP a) an \fIaction list\fR which: .LP 1) may contain outgoing events and/or specific actions; .LP 2) always contains the resultant state; .LP or .LP b) one or more \fIconditional action lists\fR , each consisting of: .LP 1) a predicate expression comprising predicates and Boolean operators; .LP 2) an action list (as in \(sc\ A.3.2 a)). .PP \fINote\fR \ \(em\ The action lists and conditional action lists use the notation in \(sc\ A.2. .PP A.3.3 The intersection of each state and incoming event which is not logically possible for the SPM is indicated by\ // in the top lefthand corner of the intersection. .PP \fINote\fR \ \(em\ Such entries are a consequence of the tabular presentation of the state tables. .sp 2P .LP A.4 \fIActions to be taken by the SPM\fR .sp 1P .RT .PP The state tables define the action to be taken by the SPM. .RT .sp 1P .LP A.4.1 \fIInvalid intersections\fR .sp 9p .RT .PP If the intersection of the state and an incoming event is invalid, one of the following actions shall be taken. \v'3p' .RT .LP A.4.1.1\ \ If the incoming event comes from the SS\(hyuser, any action taken by the SPM is a local matter. .LP A.4.1.2\ \ If the incoming event is related to a received SPDU and if the state of the transport connection makes it possible, the SPM shall either: .LP a) take the following actions: .LP 1) issue an S\(hyP\(hyABORT indication; .LP 2) send an ABORT SPDU; .LP 3) start the timer, TIM; .LP 4) wait for a T\(hyDISCONNECT indication or an ABORT ACCEPT SPDU (STA\ 16); or .LP b) if the following conditions hold: .LP 1) the data token is available but not assigned to the SPM; and .LP 2) \(em the activity management functional unit has not been selected; or .LP \(em the activity management functional unit has been selected and an activity is in progress; or .LP \(em the activity management functional unit has been selected and the SPM is in STA\ 22; and .bp .LP 3) the exceptions functional unit has been selected; and .LP 4) the session connection is in the data transfer phase (i.e. states 4A, 4B, 5A, 5B, 5C, 6, 10A, 10B, 11A, 11B, 11C, 15A, 15B, 15C, 19, 20, 22, 713); .LP take the following actions: .LP 5) send an EXCEPTION REPORT SPDU; .LP 6) issue an S\(hyP\(hyEXCEPTION\(hyREPORT indication; .LP 7) enter STA 20 and wait for a recovery request or SPDU. .LP \fINote:\fR \ \(em\ It should be noted that sending an EXCEPTION REPORT SPDU may lead to an SPM deadlock. It is therefore advised to send the ABORT\ SPDU rather than the EXCEPTION REPORT\ SPDU, especially in the case of protocol errors. .LP A.4.1.3\ \ If the incoming event falls into neither of the above categories (including those which are impossible by the definition of the behaviour of the SPM or TS\(hyprovider) any action taken by the SPM is a local matter. .sp 1P .LP A.4.2 \fIValid intersections\fR .sp 9p .RT .PP If the intersection of the state and incoming event is valid, one of the following actions shall be taken. .RT .LP A.4.2.1\ \ If the intersection contains an action list, the SPM shall take the specific actions in the order specified in the state table. .LP A.4.2.2\ \ If the intersection contains one or more conditional action lists, for each predicate expression that is true the SPM shall take the specific actions in the order given in the action list associated with the predicate expression. If none of the predicate expressions are true, the SPM shall take one of the actions defined in \(sc\ A.4.1. .sp 1P .LP A.4.2.3\ \ \fIProcedures for segmented SSDUs\fR .sp 9p .RT .PP The state tables do not take account of segmented SSDUs. When an outgoing SSDU is to be segmented or an incoming SSDU is segmented, the procedures defined in \(sc\ 7.37 apply to the outgoing event at the appropriate intersection of the state tables (that part of the action which transmits the SPDU). .RT .sp 2P .LP A.4.3 \fIReceipt of SPDUs\fR .sp 1P .RT .sp 1P .LP A.4.3.1\ \ \fIValid SPDUs\fR .sp 9p .RT .PP The SPM shall process valid SPDUs as specified in Tables\ A\(hy7/X.225 to A\(hy15/X.225. .RT .sp 1P .LP A.4.3.1.1\ \ \fIRules of extensibility\fR .sp 9p .RT .PP This Recommendation does not specify the action to be taken in response to a PGI unit containing a PGI code listed in Annex\ C, or to a PI unit containing a PI code listed in Annex\ C. .PP An SPM receiving an SPDU containing a valid SI field but containing a PGI unit whose PGI code is not specified in \(sc\ 8.3 or in Annex\ C, shall ignore that PGI unit (see notes). .PP An SPM reciving an SPDU containing a valid SI field but containing a PI unit whose PI code is not specified in \(sc\ 8.3 or in Annex\ C, shall ignore that PI unit (see notes). .PP The SPM shall ignore any bits within a parameter field which are specified as reserved in \(sc\ 8.3. .PP \fINote\ 1\fR \ \(em\ The received SPDU is processed as through the unknown PGI and/or PI units were not present in the SPDU. .PP \fINote\ 2\fR \ \(em\ The provisions permit communication with systems operating other versions of this protocol. .RT .sp 1P .LP A.4.3.1.2\ \ \fIUser Data length restrictions\fR .sp 9p .RT .PP If an SPM receives an SPDU, or an ordered sequence of SPDUs which together comprise a single SSDU, which contains more SS\(hyuser data than the SPM is prepared to accept (and as stated in the\ PICS), it shall take the actions defined in either \(sc\ A.4.1.2\ a) or \(sc\ A.4.1.2\ b). .bp .RT .sp 1P .LP A.4.3.2\ \ \fIInvalid SPDUs\fR .sp 9p .RT .PP If an invalid SPDU is received, the SPM shall: .RT .LP a) take the actions defined in \(sc\ A.4.1.2\ a); or .LP b) take the actions defined in \(sc\ A.4.1.2\ b); or .LP c) take any other action that does not violate the procedures specified in this Recommendation; or .LP d) take no action. .sp 1P .LP A.5 \fIDefinitions of sets and variables\fR .sp 9p .RT .PP The following sets and variables are specified in this Recommendation. .RT .sp 1P .LP A.5.1 \fIFunctional units\fR .sp 9p .RT .PP The set of all functional units specified in this Recommendation is defined as: .RT .LP fu\(hydom = {FD, HD, EXCEP, TD, NR, SY, MA, RESYN, EX, ACT, CD} .LP where .LP FD =\ Duplex functional unit .LP HD =\ Half\(hyduplex functional unit .LP EXCEP =\ Exceptions functional unit .LP TD =\ Typed data functional unit .LP NR =\ Negotiated release functional unit .LP SY =\ Minor synchronize functional unit .LP MA =\ Major synchronize functional unit .LP RESYN =\ Resynchronize functional unit .LP EX =\ Expedited data functional unit .LP ACT =\ Activity management functional unit .LP CD =\ Capability data functional unit .PP A Boolean function FU is defined over fu\(hydom as follows: .LP for f in fu\(hydom .LP FU(f)\ =\ true: if and only if the functional unit f has been selected during the session connection establishment phase. .PP The value is set when the ACCEPT SPDU is sent or received. .sp 1P .LP A.5.2 \fITokens\fR .sp 9p .RT .PP The set of all tokens specified in this Recommendation is defined as: .RT .LP tk\(hydom = {mi, ma, tr, dk} .LP where .LP mi =\ synchronize\(hyminor token .LP ma =\ major/activity token .LP tr =\ release token .LP dk =\ data token .PP The following Boolean functions are defined over tk\(hydom: .LP a) AV(t), for t in tk\(hydom, is a function which defines the availability of the corresponding token and has the following values: .LP AV(mi) =\ FU(SY) .LP AV(dk) =\ FU(HD) .LP AV(tr) =\ FU(NR) .LP AV(ma) =\ FU(MA) or FU(ACT) .LP b) OWNED(t), for t in tk\(hydom, is a function which defines the assignment of the corresponding token and is defined as: .LP OWNED(t)\ =\ true: if token assigned to the SPM .LP OWNED(t)\ =\ false: if token not assigned to the SPM .bp .LP OWNED(t) is not defined if AV(t) = false. OWNED(t) is set when: .LP 1) the ACCEPT SPDU is sent or received; or .LP 2) the RESYNCHRONIZE ACK SPDU is sent or received; or .LP 3) the GIVE TOKENS SPDU is sent or received; or .LP 4) the GIVE TOKENS CONFIRM SPDU is sent or received; .LP 5) the ACTIVITY INTERRUPT ACK SPDU is sent or received; .LP 6) the ACTIVITY DISCARD ACK SPDU is sent or received. .LP c) I(t), for t in tk\(hydom, is a function which, when true, indicates that the SPM has \fII\fR nitiating rights for the behaviour controlled by the token. This applies even if the corresponding token is not available: .LP I(t)\ =\ \*\|iAV(t) OR OWNED(t) .LP d) A(t), for t in tk\(hydom, is a function which, when true, indicates that the SPM has \fIA\fR ccepting rights for the behaviour controlled by the token. This applies even if the corresponding token is not available: .LP A(t)\ =\ \*\|iAV(t) OR \ \*\|iOWNED(t) .LP e) II(t), for t in tk\(hydom, is a function which, when true, indicates that the SPM has \fII\fR nitiating rights as I(t), but this applies to the case when the behaviour may only be initiated if the corresponding token is available and owned: .LP II(t)\ =\ AV(t) AND OWNED(t) .LP f ) AA(t), for t in tk\(hydom, is a function which, when true, indicates that the SPM has \fIA\fR ccepting rights as A(t), but only if the corresponding token is available, but not owned: .LP AA(t)\ =\ AV(t) AND\ \*\|iOWNED(t) .sp 1P .LP A.5.3 \fISET of tokens\fR .sp 9p .RT .PP The following subsets of tk\(hydom are defined: .RT .LP RT =\ {tokens requested in the input event} .LP GT =\ {tokens given in the input event} .PP For the purpose of the following function definitions, two further set are defined: .LP F =\ {AV, OWNED, I, A, II, AA} (the set of functions defined in \(sc\ A.5.2); .LP S =\ the set of subsets of tk\(hydom. .PP The following functions are defined over F and S: .LP a) ALL(f, s) for f in F and s in S: .LP ALL(f,\ s)\ =\ true: all of the f(t) for t in s are true or s is empty. .LP For example: .LP ALL(A,\ tk\(hydom)\ =\ true: none of the available tokens are owned (e.g.\ on receipt of a FINISH SPDU). .LP b) ANY(f, s), for f in F and s in S: .LP ANY(f,\ s)\ =\ true: any f(t) = true for t in s when s is not empty. .LP For example: .LP ANY(II, tk\(hydom)\ =\ true: at least one of the available tokens is owned. .sp 2P .LP A.5.4 \fIVariables\fR .sp 1P .RT .sp 1P .LP A.5.4.1\ \ \fITEXP\fR .sp 9p .RT .PP TEXP is a Boolean variable having the following values: .RT .LP TEXP\ =\ true: use of transport expedited service is selected for use on this session connection. .LP TEXP\ =\ false: use of transport expedited service is not selected for use on this session connection. .bp .sp 1P .LP A.5.4.2\ \ \fIVact\fR .sp 9p .RT .PP Vact is a Boolean variable having the following values when the activity management functional unit has been selected (FU(ACT)\ =\ true): .RT .LP Vact\ =\ true: an activity is in progress; .LP Vact\ =\ false: no activity is in progress; .PP Vact has no defined value if FU(ACT) = false. .PP Vact is set as follows: .RT .LP a) Vact is set false during the connection establishment phase, if the activity management functional unit has been selected (FU(ACT)\ =\ true). Otherwise, Vact is not set; .LP b) Vact is set true when the ACTIVITY START SPDU or ACTIVITY RESUME SPDU is sent or received (only possible when FU(ACT)\ =\ true); .LP c) Vact is set false when the ACTIVITY DISCARD ACK SPDU or ACTIVITY INTERRUPT ACK SPDU is sent or received; .LP d) Vact is set to Vnextact when a MAJOR SYNC ACK SPDU or an ACTIVITY END ACK SPDU is sent or received. .sp 1P .LP A.5.4.3\ \ \fIVnextact\fR .sp 9p .RT .PP Vnextact is a Boolean variable which is used when the activity management functional unit has been selected (FU(ACT) = true). It is used to indicate the next value of Vact when a MAJOR SYNC ACK SPDU or an ACTIVITY END ACK SPDU is sent or received. Vnextact is set when a MAJOR SYNC POINT SPDU or an ACTIVITY END SPDU is sent or received: .RT .LP a) Vnextact is set false if FU(ACT) = true and an ACTIVITY END SPDU is sent or received; .LP b) Vnextact is set true if FU(ACT) = true and a MAJOR SYNC POINT SPDU is sent or received. .PP Vnextact has not defined value if FU(ACT) = false. .sp 1P .LP A.5.4.4\ \ \fIVrsp and Vrspnb\fR .sp 9p .RT .PP These variables are used to resolve resynchronization collisions. .PP Vrsp indicates what kind of resynchronization is currently in progress: .RT .LP Vrsp\ =\ no no resynchronization in progress .LP Vrsp\ =\ a resynchronize abandon .LP Vrsp\ =\ r resynchronize restart .LP Vrsp\ =\ s resynchronize set .LP Vrsp\ =\ dsc discard activity .LP Vrsp\ =\ int interrupt activity .PP Vrspnb indicates the serial number in the case of resynchronize restart. .PP Vrsp and, if necessary Vrspnb, are set when a RESYNCHRONIZE SPDU, ACTIVITY INTERRUPT SPDU or an ACTIVITY DISCARD SPDU is sent or received. Vrsp is set to no when the SPM goes to STA\ 713. .RT .sp 1P .LP A.5.4.5\ \ \fISPMwinner\fR .sp 9p .RT .PP SPMwinner is a Boolean function which is used during resynchronization collision, that is when: .RT .LP a) a RESYNCHRONIZE SPDU is received and Vrsp is not equal to no; .LP b) an S\(hyRESYNCHRONIZE request is received and Vrsp is not equal to no. .PP The SPMwinner condition is true if the SPM (which holds the current resynchronization) wins against the new colliding event. .bp .PP The SPMwinner condition is calculated as follows: .RT .LP a) the next Vrsp and Vrspnb values are evaluated according to the parameters of the received event. The new calculated value for Vrsp is compared to the current Vrsp with the following ordering rule: .LP dsc prevails over\ int .LP int prevails over\ a .LP a prevails over\ s .LP s prevails over\ r .LP If both are equal to r, then the new calculated value for Vrspnb is compared to the current value of Vrspnb and the lower value prevails; .LP b) If the current value of Vrsp (and Vrspnb if necessary) prevails, then the SPMwinner condition is true (in this case, the current resynchronization prevails over the colliding one); .LP c) If the current value of Vrsp (and Vrspnb if necessary) does not prevail, then the SPMwinner condition is false (in this case, the colliding resynchronization prevails over the current one); .LP d) If the above comparison results in the equality and if the colliding event has been generated by the initiator of the session connection (either a RESYNCHRONIZE SPDU was received from the session connection initiator or a local S\(hyRESYNCHRONIZE request was issued by the session connection initiator), then the SPMwinner condition is false. .PP If the SPM is winner (SPMwinner condition is true) then the current resynchronization wins against the colliding one and Vrsp and Vrspnb are not updated. .PP If the SPM is not winner (SPMwinner condition is false) then the colliding resynchronization is taken into account and Vrsp and Vrspnb are updated. .RT .sp 1P .LP A.5.4.6\ \ \fIVtca\fR .sp 9p .RT .PP Vtca is a Boolean variable having the following values: .RT .LP Vtca\ =\ false: the SPM initiated the T\(hyCONNECT request (transport connection initiator); .LP Vtca\ =\ true: the SPM received the T\(hyCONNECT indication (transport connection acceptor). .sp 1P .LP A.5.4.7\ \ \fIVtrr\fR .sp 9p .RT .PP Vtrr is a Boolean variable having the following values: .RT .LP Vtrr\ =\ true: the transport connection can be reused by the SPM for another session connection; .LP Vtrr\ =\ false: the transport connection cannot be reused by the SPM for another session connection. .sp 1P .LP A.5.4.8\ \ \fIVcoll\fR .sp 9p .RT .PP Vcoll is a Boolean variable having the following values: .RT .LP Vcoll\ =\ true: a collision of FINISH SPDUs has been detected; .LP Vcoll\ =\ false: there has not been a collision of FINISH SPDUs. .PP This variable is set false during the session connection establishment phase. .sp 1P .LP A.5.4.9\ \ \fIVdnr\fR .sp 9p .RT .PP Vdnr is a Boolean variable having the following values: .RT .LP Vdnr\ =\ true: a DISCONNECT SPDU has been received in STA09 (following a collision of FINISH SPDUs); .LP Vdnr\ =\ false: no DISCONNECT SPDU has been received. .PP This variable is set to false during the session connection establishment phase. .bp .sp 1P .LP A.5.4.10\ \ \fIV(A)\fR .sp 9p .RT .PP V(A) is used by the SPM and is the lowest serial number to which a synchronization point confirmation is expected. No confirmation is expected when V(A)\ =\ V(M). .RT .sp 1P .LP A.5.4.11\ \ \fIV(M)\fR .sp 9p .RT .PP V(M) is used by the SPM and is the next serial number to be used. .RT .sp 1P .LP A.5.4.12\ \ \fIV(R)\fR .sp 9p .RT .PP V(R) is used by the SPM and is the lowest serial number to which resynchronization restart is permitted. .RT .sp 1P .LP A.5.4.13\ \ \fIVsc\fR .sp 9p .RT .PP Vsc is a Boolean variable having the following values: .RT .LP Vsc\ =\ true: the SS\(hyuser has the right to issue minor synchronization point responses when V(A) is less than V(M); .LP Vsc\ =\ false: the SS\(hyuser does not have the right to issue minor synchronization point responses. .PP Vsc is set false during the connection establishment phase and when a MINOR SYNC POINT SPDU is sent. Vcs is set true when a MINOR SYNC POINT SPDU is received. .PP \fINote\fR \ \(em\ Table\ A\(hy4/X.225 summarizes the operations on V(A), V(M), V(R) and Vsc. .RT .LP .rs .sp 28P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T47.225]\fR .ce TABLE\ A\(hy1/X.225 .ce \fBIncoming Events\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . SACTDreq SS\(hyuser T{ S\(hyACTIVITY\(hyDISCARD request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTDrsp SS\(hyuser T{ S\(hyACTIVITY\(hyDISCARD response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTEreq SS\(hyuser T{ S\(hyACTIVITY\(hyEND request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTErsp SS\(hyuser T{ S\(hyACTIVITY\(hyEND response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTIreq SS\(hyuser T{ S\(hyACTIVITY\(hyINTERRUPT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTIrsp SS\(hyuser T{ S\(hyACTIVITY\(hyINTERRUPT response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTRreq SS\(hyuser T{ S\(hyACTIVITY\(hyRESUME request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTSreq SS\(hyuser T{ S\(hyACTIVITY\(hySTART request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCDreq SS\(hyuser T{ S\(hyCAPABILITY\(hyDATA request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCDrsp SS\(hyuser T{ S\(hyCAPABILITY\(hyDATA response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCGreq SS\(hyuser T{ S\(hyCONTROL\(hyGIVE request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONreq SS\(hyuser T{ S\(hyCONNECT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONrsp+ SS\(hyuser T{ S\(hyCONNECT (accept) response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONrsp\(em SS\(hyuser T{ S\(hyCONNECT (reject) response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SDTreq SS\(hyuser S\(hyDATA request primitive .T& lw(42p) | lw(66p) | lw(120p) . SEXreq SS\(hyuser T{ S\(hyEXPEDITED\(hyDATA request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SGTreq SS\(hyuser T{ S\(hyTOKEN\(hyGIVE request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SPTreq SS\(hyuser T{ S\(hyTOKEN\(hyPLEASE request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELreq SS\(hyuser T{ S\(hyRELEASE request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELrsp+ SS\(hyuser T{ S\(hyRELEASE (accept) response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELrsp\(em SS\(hyuser T{ S\(hyRELEASE (reject) response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNreq(a) SS\(hyuser T{ S\(hyRESYNCHRONIZE (abandon) request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNreq(r) SS\(hyuser T{ S\(hyRESYNCHRONIZE (restart) request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNreq(s) SS\(hyuser T{ S\(hyRESYNCHRONIZE (set) request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNrsp SS\(hyuser T{ S\(hyRESYNCHRONIZE response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNMreq SS\(hyuser T{ S\(hySYNC\(hyMAJOR request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNMrsp SS\(hyuser T{ S\(hySYNC\(hyMAJOR response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNmreq SS\(hyuser T{ S\(hySYNC\(hyMINOR request primitive T} _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy1/X.225, [1T47.225] p.1\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T47.225]\fR .ce TABLE\ A\(hy1/X.225 \fI(cont.)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . SSYNmrsp SS\(hyuser T{ S\(hySYNC\(hyMINOR response primitive \fR T} .T& lw(42p) | lw(66p) | lw(120p) . STDreq SS\(hyuser T{ S\(hyTYPED\(hyDATA request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SUABreq SS\(hyuser T{ S\(hyU\(hyABORT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SUERreq SS\(hyuser T{ S\(hyU\(hyEXCEPTION\(hyREPORT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TCONind TS\(hyprovider T{ T\(hyCONNECT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TCONcnf TS\(hyprovider T{ T\(hyCONNECT confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TDISind TS\(hyprovider T{ T\(hyDISCONNECT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TIM Timer Time out .T& lw(42p) | lw(66p) | lw(120p) . AA SPDU ABORT ACCEPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . AB\(hynr SPDU ABORT (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . AB\(hyr SPDU ABORT (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . AC SPDU ACCEPT SPDU (see Note\ 1) .T& lw(42p) | lw(66p) | lw(120p) . AD SPDU ACTIVITY DISCARD SPDU .T& lw(42p) | lw(66p) | lw(120p) . ADA SPDU ACTIVITY DISCARD ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AE SPDU ACTIVITY END SPDU .T& lw(42p) | lw(66p) | lw(120p) . AEA SPDU ACTIVITY END ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AI SPDU ACTIVITY INTERRUPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . AIA SPDU ACTIVITY INTERRUPT ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AR SPDU ACTIVITY RESUME SPDU .T& lw(42p) | lw(66p) | lw(120p) . AS SPDU ACTIVITY START SPDU .T& lw(42p) | lw(66p) | lw(120p) . CD SPDU CAPABILITY DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . CDA SPDU CAPABILITY DATA ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . CDO SPDU CONNECT DATA OVERFLOW SPDU .T& lw(42p) | lw(66p) | lw(120p) . CN SPDU CONNECT SPDU .T& lw(42p) | lw(66p) | lw(120p) . DN SPDU DISCONNECT SPDU .T& lw(42p) | lw(66p) | lw(120p) . DT SPDU DATA TRANSFER SPDU .T& lw(42p) | lw(66p) | lw(120p) . ED SPDU EXCEPTION DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . ER SPDU EXCEPTION REPORT SPDU .T& lw(42p) | lw(66p) | lw(120p) . EX SPDU EXPEDITED DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . FN\(hynr SPDU FINISH (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . FN\(hyr SPDU FINISH (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . GT SPDU T{ GIVE TOKENS SPDU with Token Item parameter (see Note\ 2) T} .T& lw(42p) | lw(66p) | lw(120p) . GTA SPDU GIVE TOKENS ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . GTC SPDU GIVE TOKENS CONFIRM SPDU .T& lw(42p) | lw(66p) | lw(120p) . MAA SPDU MAJOR SYNC ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . MAP SPDU MAJOR SYNC POINT SPDU .T& lw(42p) | lw(66p) | lw(120p) . MIA SPDU MINOR SYNC ACK SPDU _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy1/X.225, [2T47.225] p.2\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [3T47.225]\fR .ce TABLE\ A\(hy1/X.225 \fI(end)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . MIP SPDU MINOR SYNC POINT SPDU .T& lw(42p) | lw(66p) | lw(120p) . NF SPDU NOT FINISHED SPDU .T& lw(42p) | lw(66p) | lw(120p) . OA SPDU OVERFLOW ACCEPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyAB SPDU PREPARE (ABORT) SPDU .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyMAA SPDU PREPARE (MAJOR SYNC ACK) SPDU .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyRA SPDU T{ PREPARE (RESYNCHRONIZE ACK) SPDU T} .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyRS SPDU PREPARE (RESYNCHRONIZE) SPDU .T& lw(42p) | lw(66p) | lw(120p) . PT SPDU T{ PLEASE TOKENS SPDU with Token Item parameter (see Notes 1 and\ 2) T} .T& lw(42p) | lw(66p) | lw(120p) . RA SPDU RESYNCHRONIZE ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . RF\(hynr SPDU REFUSE (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RF\(hyr SPDU REFUSE (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hya SPDU RESYNCHRONIZE (abandon) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hyr SPDU RESYNCHRONIZE (restart) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hys SPDU RESYNCHRONIZE (set) SPDU .T& lw(42p) | lw(66p) | lw(120p) . TD SPDU T{ TYPED DATA SPDU \fINote\ 1\fR \ \(em\ If the Token Item parameter is present in the ACCEPT SPDU, both the AC event and the PT event occur. .parag \fINote\ 2\fR \ \(em\ GIVE TOKENS SPDU without Token Item parameter and PLEASE TOKENS SPDU without Token Item parameter are used to herald a concatenated sequence of SPDUs Concatenation of SPDUs and separation of TSDUs are not handled by the state tables. .parag T} _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy1/X.225, [3T47.225] p.3\fR .sp 1P .RT .ad b .RT .LP .rs .sp 19P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [T48.225]\fR .ce TABLE\ A\(hy2/X.225 .ce \fBStates\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(48p) | cw(180p) . Abbreviated name Name and description _ .T& lw(48p) | lw(180p) . STA 01 Idle, no transport connection .T& lw(48p) | lw(180p) . STA 01A T{ Wait for the ABORT ACCEPT SPDU T} .T& lw(48p) | lw(180p) . STA 01B Wait for T\(hyCONNECT confirm .T& lw(48p) | lw(180p) . STA 01C Idle, transport connected .T& lw(48p) | lw(180p) . STA 01D T{ Wait for the CONNECT DATA OVERFLOW SPDU T} .T& lw(48p) | lw(180p) . STA 02A Wait for the ACCEPT SPDU .T& lw(48p) | lw(180p) . STA 02B T{ Wait for the OVERFLOW ACCEPT SPDU T} .T& lw(48p) | lw(180p) . STA 03 Wait for the DISCONNECT SPDU .T& lw(48p) | lw(180p) . STA 04A T{ Wait for the MAJOR SYNC ACK SPDU or PREPARE (MAJOR SYNC ACK) SPDU T} .T& lw(48p) | lw(180p) . STA 04B T{ Wait for the ACTIVITY END ACK SPDU or PREPARE (MAJOR SYNC ACK) SPDU T} .T& lw(48p) | lw(180p) . STA 05A T{ Wait for the RESYNCHRONIZE ACK SPDU or PREPARE (RESYNCHRONIZE ACK) SPDU T} .T& lw(48p) | lw(180p) . STA 05B T{ Wait for the ACTIVITY INTERRUPT ACK SPDU or PREPARE (RESYNCHRONIZE ACK) SPDU T} .T& lw(48p) | lw(180p) . STA 05C T{ Wait for the ACTIVITY DISCARD ACK SPDU or PREPARE (RESYNCHRONIZE ACK) SPDU T} .T& lw(48p) | lw(180p) . STA 06 T{ Wait for the RESYNCHRONIZE SPDU [resynchronization collision after receiving PREPARE (RESYNCHRONIZE) SPDU] T} .T& lw(48p) | lw(180p) . STA 08 T{ Wait for S\(hyCONNECT response T} .T& lw(48p) | lw(180p) . STA 09 T{ Wait for S\(hyRELEASE response T} .T& lw(48p) | lw(180p) . STA 10A T{ Wait for S\(hySYNC\(hyMAJOR response T} .T& lw(48p) | lw(180p) . STA 10B T{ Wait for S\(hyACTIVITY\(hyEND response T} .T& lw(48p) | lw(180p) . STA 11A T{ Wait for S\(hyRESYNCHRONIZE response T} .T& lw(48p) | lw(180p) . STA 11B T{ Wait for S\(hyACTIVITY\(hyINTERRUPT response T} .T& lw(48p) | lw(180p) . STA 11C T{ Wait for S\(hyACTIVITY\(hyDISCARD response T} .T& lw(48p) | lw(180p) . STA 15A T{ After PREPARE, wait for the MAJOR SYNC ACK SPDU or the ACTIVITY END ACK SPDU T} .T& lw(48p) | lw(180p) . STA 15B T{ After PREPARE, wait for the RESYNCHRONIZE SPDU or the ACTIVITY INTERRUPT SPDU or the ACTIVITY DISCARD SPDU T} .T& lw(48p) | lw(180p) . STA 15C T{ After PREPARE, wait for the RESYNCHRONIZE ACK SPDU or the ACTIVITY INTERRUPT ACK SPDU or the ACTIVITY DISCARD ACK SPDU T} .T& lw(48p) | lw(180p) . STA 15D T{ After PREPARE, wait for the ABORT SPDU T} .T& lw(48p) | lw(180p) . STA 16 T{ Wait for T\(hyDISCONNECT indication T} .T& lw(48p) | lw(180p) . STA 18 T{ Wait for the GIVE TOKENS ACK SPDU T} .T& lw(48p) | lw(180p) . STA 19 T{ Wait for a recovery request or SPDU (initiator of EXCEPTION DATA SPDU) T} .T& lw(48p) | lw(180p) . STA 20 T{ Wait for a recovery SPDU or request T} .T& lw(48p) | lw(180p) . STA 21 T{ Wait for the CAPABILITY DATA ACK SPDU T} .T& lw(48p) | lw(180p) . STA 22 T{ Wait for S\(hyCAPABILITY\(hyDATA response T} .T& lw(48p) | lw(180p) . STA 713 Data transfer state _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy2/X.225, [T48.225] p.4\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T49.225]\fR .ce TABLE\ A\(hy3/X.225 .ce \fBOutgoing Events\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . SACTDind SS\(hyprovider T{ S\(hyACTIVITY\(hyDISCARD indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTDcnf SS\(hyprovider T{ S\(hyACTIVITY\(hyDISCARD confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTEind SS\(hyprovider T{ S\(hyACTIVITY\(hyEND indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTEcnf SS\(hyprovider T{ S\(hyACTIVITY\(hyEND confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTIind SS\(hyprovider T{ S\(hyACTIVITY\(hyINTERRUPT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTIcnf SS\(hyprovider T{ S\(hyACTIVITY\(hyINTERRUPT confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTRind SS\(hyprovider T{ S\(hyACTIVITY\(hyRESUME indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SACTSind SS\(hyprovider T{ S\(hyACTIVITY\(hySTART indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCDind SS\(hyprovider T{ S\(hyCAPABILITY\(hyDATA indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCDcnf SS\(hyprovider T{ S\(hyCAPABILITY\(hyDATA confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCGind SS\(hyprovider T{ S\(hyCONTROL\(hyGIVE indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONind SS\(hyprovider T{ S\(hyCONNECT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONcnf+ SS\(hyprovider T{ S\(hyCONNECT (accept) confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SCONcnf\(em SS\(hyprovider T{ S\(hyCONNECT (reject) confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SDTind SS\(hyprovider T{ S\(hyDATA indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SEXind SS\(hyprovider T{ S\(hyEXPEDITED\(hyDATA indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SGTind SS\(hyprovider T{ S\(hyTOKEN\(hyGIVE indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SPABind SS\(hyprovider T{ S\(hyP\(hyABORT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SPERind SS\(hyprovider T{ S\(hyP\(hyEXCEPTION\(hyREPORT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SPTind SS\(hyprovider T{ S\(hyTOKEN\(hyPLEASE indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELind SS\(hyprovider T{ S\(hyRELEASE indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELcnf+ SS\(hyprovider T{ S\(hyRELEASE (accept) confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRELcnf\(em SS\(hyprovider T{ S\(hyRELEASE (reject) confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNind SS\(hyprovider T{ S\(hyRESYNCHRONIZE indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SRSYNcnf SS\(hyprovider T{ S\(hyRESYNCHRONIZE confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNMind SS\(hyprovider T{ S\(hySYNC\(hyMAJOR indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNMcnf SS\(hyprovider T{ S\(hySYNC\(hyMAJOR confirm primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNmind SS\(hyprovider T{ S\(hySYNC\(hyMINOR indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SSYNmcnf SS\(hyprovider T{ S\(hySYNC\(hyMINOR confirm primitive T} _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy3/X.225, [1T49.225] p.5\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T49.225]\fR .ce TABLEAU\ A\(hy3/X.225 \fI(cont.)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . STDind SS\(hyprovider T{ S\(hyTYPED\(hyDATA indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SUABind SS\(hyprovider T{ S\(hyU\(hyABORT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . SUERind SS\(hyprovider T{ S\(hyU\(hyEXCEPTION\(hyREPORT indication primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TCONreq TS\(hyuser T{ T\(hyCONNECT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TCONrsp TS\(hyuser T{ T\(hyCONNECT response primitive T} .T& lw(42p) | lw(66p) | lw(120p) . TDISreq TS\(hyuser T{ T\(hyDISCONNECT request primitive T} .T& lw(42p) | lw(66p) | lw(120p) . AA SPDU ABORT ACCEPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . AB\(hynr SPDU ABORT (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . AB\(hyr SPDU ABORT (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . AC SPDU ACCEPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . AD SPDU ACTIVITY DISCARD SPDU .T& lw(42p) | lw(66p) | lw(120p) . ADA SPDU ACTIVITY DISCARD ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AE SPDU ACTIVITY END SPDU .T& lw(42p) | lw(66p) | lw(120p) . AEA SPDU ACTIVITY END ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AI SPDU ACTIVITY INTERRUPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . AIA SPDU ACTIVITY INTERRUPT ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . AR SPDU ACTIVITY RESUME SPDU .T& lw(42p) | lw(66p) | lw(120p) . AS SPDU ACTIVITY START SPDU .T& lw(42p) | lw(66p) | lw(120p) . CD SPDU CAPABILITY DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . CDA SPDU CAPABILITY DATA ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . CDO SPDU CONNECT DATA OVERFLOW SPDU .T& lw(42p) | lw(66p) | lw(120p) . CN SPDU CONNECT SPDU .T& lw(42p) | lw(66p) | lw(120p) . DN SPDU DISCONNECT SPDU .T& lw(42p) | lw(66p) | lw(120p) . DT SPDU DATA TRANSFERT SPDU .T& lw(42p) | lw(66p) | lw(120p) . ED SPDU EXCEPTION DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . EX SPDU EXPEDITED DATA SPDU .T& lw(42p) | lw(66p) | lw(120p) . FN\(hynr SPDU FINISH (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . FN\(hyr SPDU FINISH (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . GT SPDU GIVE TOKENS SPDU .T& lw(42p) | lw(66p) | lw(120p) . GTA SPDU GIVE TOKENS ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . GTC SPDU GIVE TOKENS CONFIRM SPDU .T& lw(42p) | lw(66p) | lw(120p) . MAA SPDU MAJOR SYNC ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . MAP SPDU MAJOR SYNC POINT SPDU .T& lw(42p) | lw(66p) | lw(120p) . MIA SPDU MINOR SYNC ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . MIP SPDU MINOR SYNC POINT SPDU .T& lw(42p) | lw(66p) | lw(120p) . NF SPDU NOT FINISHED SPDU .T& lw(42p) | lw(66p) | lw(120p) . OA SPDU OVERFLOW ACCEPT SPDU .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyMAA SPDU PREPARE (MAJOR SYNC ACK) SPDU .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyAB SPDU PREPARE (ABORT) SPDU _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy3/X.225, [2T49.225] p.6\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [3T49.225]\fR .ce TABLE\ A\(hy3/X.225 \fI(end)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(42p) | cw(66p) | cw(120p) . Abbreviated name Category Name and description _ .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyRA SPDU T{ PREPARE (RESYNCHRONIZE ACK) SPDU T} .T& lw(42p) | lw(66p) | lw(120p) . PR\(hyRS SPDU PREPARE (RESYNCHRONIZE) SPDU .T& lw(42p) | lw(66p) | lw(120p) . PT SPDU PLEASE TOKENS SPDU .T& lw(42p) | lw(66p) | lw(120p) . RA SPDU RESYNCHRONIZE ACK SPDU .T& lw(42p) | lw(66p) | lw(120p) . RF\(hynr SPDU REFUSE (not reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RF\(hyr SPDU REFUSE (reuse) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hya SPDU RESYNCHRONIZE (abandon) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hyr SPDU RESYNCHRONIZE (restart) SPDU .T& lw(42p) | lw(66p) | lw(120p) . RS\(hys SPDU RESYNCHRONIZE (set) SPDU .T& lw(42p) | lw(66p) | lw(120p) . TD SPDU TYPED DATA SPDU _ .TE .nr PS 9 .RT .ad r \fBTableau A\(hy3/X.225, [3T49.225] p.7\fR .sp 1P .RT .ad b .RT .LP .rs .sp 31P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [T50.225]\fR .T& lw(36p) | lw(84p) | lw(72p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .T& lw(36p) | lw(84p) | lw(72p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ set to sn + 1 unchanged unchanged unchanged SRSYNreq a: not applicable r: V(M) >= sn >= V(R) s: sn <= 999 999 abandon restart set unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged RS SPDU a: sn <= 999 999 r: sn >= V(R) s: sn <= 999 999 abandon restart set unchanged unchanged unchanged max (sn, V(M)) unchanged unchanged unchanged unchanged unchanged unchanged unchanged unchanged SRSYNrsp a: sn = V(M) r: sn as in RS SPDU s: sn <= 999 999 abandon restart set set to sn set to sn set to sn set to sn set to sn set to sn 0 unchanged 0 unchanged unchanged unchanged RA SPDU a: sn >= V(M) r: sn as in RS SPDU s: sn <= 999 999 abandon restart set set to sn set to sn set to sn set to sn set to sn set to sn 0 unchanged 0 unchanged unchanged unchanged SACTRreq .line AR SPDU . set to sn + 1 set to sn + 1 set to 1 unchanged SACTSreq AS SPDU . set to 1 set to 1 set to 1 unchanged SCONrsp AC SPDU . sn present set to sn set to sn 0 false sn: synchronization point serial number quoted in SS\(hyuser request or SPDU .line >=: greater than or equal to .line <=: less than or equal to .line *: synchronization point serial number not equal to V(M) \(em 1 if major synchronization or activity end outstanding T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy4/X.225 (\*`a l'italienne), [T50.225] p.8\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [T51.225]\fR .ce TABLE\ A\(hy5/X.225 .ce \fBSpecific actions\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(24p) | lw(204p) . .T& lw(24p) | lw(204p) . T{ Set V(M) = V(M) + 1 [24] If Vsc = true, set V(A) = V(M). Set Vsc = false T} .T& lw(24p) | lw(204p) . T{ Set V(M) = V(M) + 1 [25] Set V(A) = serial number + 1 [26] Set V(A) = V(M) = V(R) = 1 [27] Set V(A) = V(M) = serial number + 1 T} .T& lw(24p) | lw(204p) . T{ Set V(R) = 1 [28] Set V(A) = V(M) = serial number T} .T& lw(24p) | lw(204p) . T{ If Vrsp = a, then set V(R) = 0 T} .T& lw(24p) | lw(204p) . T{ If Vrsp = s, then set V(R) = 0 T} .T& lw(24p) | lw(204p) . T{ Set Vrsp = no [29] Set the position of the tokens such that all available tokens are owned. Set Vact = false T} .T& lw(24p) | lw(204p) . T{ Set Vrsp = no [30] Set the position of the tokens such that all available tokens are not owned. Set Vact = false T} .T& lw(24p) | lw(204p) . T{ Set Vrsp = no [31] If Vsc = false, set V(A) = V(M) T} .T& lw(24p) | lw(204p) . T{ Set V(M) = V(M) + 1 [32] Set Vdnr = true [50] Preserve user data for subsequent SCONind [51] If p201 send subsequent CDO SPDUs until \*\|ip201 T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy5/X.225 [T51.225], p.9\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T52.225]\fR .ce TABLE\ A\(hy6/X.225 .ce \fBPredicates\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(24p) | lw(204p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy6/X.225 [1T52.225], p.10\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T52.225]\fR .ce TABLE\ A\(hy6/X.225 \fI(cont.)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; lw(24p) | lw(204p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy6/X.225 [2T52.225], p.11\fR .sp 1P .RT .ad b .RT .LP .rs .sp 13P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T53.225]\fR .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . SCONcnf+ [5] [11] STA713 [6] STA15D STA16 CDO / / .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ / / TDISreq STA01 \*\|ip202 [50] STA01D p202 SCONind STA08 T} T{ STA15D CN / / TDISreq [3] STA01 / / \*\|ip01 & \*\|ip76 & p204 OA [50] STA01D \*\|ip01 & \*\|ip76 & \*\|ip204 SCONind STA08 \*\|ip01 & p76 & \*\|ip02 RF\(hynr [4] STA16 \*\|ip01 & p76 & p02 RF\(hyr STA01C p01 TDISreq STA01 T} .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . TDISreq [3] STA01 OA / / .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . / / TDISreq STA01 CDO [51] STA02A T{ STA15D RF\(hynr / / STA01A / / TDISreq STA01 T} .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ SCONcnf\(em TDISreq STA01\fR SCONcnf\(em TDISreq STA01\fR T} STA16 .TE .nr PS 9 .RT .ad r \fBTableau A\(hy7/X.225, [1T53.225] ITALIENNE p.12 .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T53.225]\fR .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ \*\|ip02 SCONcnf\(em TDISreq STA01 p02 SCONcnf\(em STA01C \*\|ip02 SCONcnf\(em TDISreq STA01 p02 SCONcnf\(em STA01C T} T{ STA16 SCONreq TCONreq [2] STA01B T} .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ p01 & p204 CN STA02B p01 & \*\|ip204 CN STA02A T} SCONrsp+ .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ AC [5] [11] STA713 STA15D SCONrsp\(em T} .T& lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(42p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) . T{ \*\|ip02 RF\(hynr [4] STA16 p02 RF\(hyr STA01C STA15D TCONcnf / / / / p204 CN STA02B \*\|ip204 CN STA02A / / / / / / / / / / / / / / TCONind TCONrsp [1] STA01C / / / / / / / / / / / / / / / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy7/X.225, [2T53.225] ITALIENNE p.13 .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T54.225]\fR .ce TABLE\ A\(hy8/X.225 .ce \fBData transfer state table\fR .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . T{ p05&p10 SDTind STA03 p05 SDTind STA04A p05 SDTind STA04B p05 STA05A p05 STA05B EX STA01A TDISreq STA01 TDISreq STA01 [10] STA02A p09 SEXind STA03 p08 SEXind STA04A p08 SEXind STA04B p08 STA05A p08 STA05B TD STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . T{ p06&p10 STDind STA03 p06 STDind STA04A p06 STDind STA04B p06 STA05A p06 STA05B SDTreq T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . SEXreq .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STDreq .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy8/X.225, [1T54.225] p.14 .sp 1P .RT .ad b .RT .ce \fBH.T. [2T54.225]\fR .ce TABLE\ A\(hy8/X.225 \fI(cont.)\fR .ce \fBData transfer state table\fR .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . T{ p05 SDTind STA15A p05 STA15B EX p08 STA05C p08 [10] STA06 . T} .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . p08 [10] STA15A TD p06 STA05C p06 STA06 .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . T{ p06 STDind STA15A p06 STA15B SDTreq . p04 DT STA09 p03 DT STA10A p03 DT STA10B T} .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . p03 STA15B SEXreq .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . T{ p09 EX STA09 p08 EX STA10A p08 EX STA10B T} T{ p08 STA15B STDreq . p07 TD STA09 p06 TD STA10A p06 TD STA10B T} .T& lw(30p) | lw(24p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(30p) | lw(24p) . p06 STA15B .TE .nr PS 9 .RT .ad r \fBTableau A\(hy8/X.225, [2T54.225] p.15 .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [3T54.225]\fR .ce TABLE\ A\(hy8/X.225 \fI(end)\fR .ce \fBData transfer state table\fR .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . T{ STA16 p08 SEXind STA18 p08 STA19 p08 STA20 p08 SEXind STA21 p08 SEXind STA713 TD p06 STA15C STA15D STA16 p06 STDind STA18 p06 STA19 p06 STA20 p06 STDind STA21 p06 STDind STA713 SDTreq T} .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . STA15D p70 DT STA18 p03 DT STA713 SEXreq .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . STA15D p08 EX STA18 p08 EX STA713 STDreq .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . STA15D p06 TD STA18 p06 TD STA713 .TE .nr PS 9 .RT .ad r \fBTableau A\(hy8/X.225, [3T54.225] p.16 .sp 1P .RT .ad b .RT .ce \fBH.T. [1T55.225]\fR .ce TABLE\ A\(hy9/X.225 .ce \fBSynchronization state table\fR .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . p12 STA05A T{ PR\(hyMAA STA01A TDISreq STA01 TDISreq STA01 STA15A STA15A STA05A STA05B STA05C SSYNMreq . T} .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . SSYNMrsp . . . . . . .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [1T55.225] p.17 .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(cont.)\fR .ce \fBSynchronization state table\fR .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p12 STA15B p12 STA15C STA15D PR\(hyMAA SSYNMreq T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p13 STA15B STA15D SSYNMrsp .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ PR\(hyMAA (1) MAA [14] [22] STA713 T} STA15B STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [2T55.225] p.18 .sp 1P .RT .ad b .RT .ce \fBH.T. [3T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(cont.)\fR .ce \fBSynchronization state table\fR .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p20 STA20 T{ MAP STA16 p12&p19 [31] STA19 p12&p19 [31] STA20 p12&p19 SSYNMind [13] [31] STA10A PR\(hyMAA STA16 T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . SSYNMreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p13 MAP [13] [24] STA04A SSYNMrsp T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [3T55.225] p.19\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [4T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(cont.)\fR .ce \fBSynchronization state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p72 STA05A MIA STA01A TDISreq STA01 TDISreq STA01 p17&p21 SSYNmcnf [25] STA03 p17&\*\|ip20&p21 SSYNmcnf [25] STA04A p17&\*\|ip20&p21 SSYNmcnf [25] STA04B p17 STA05A MIP STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p14 STA05A SACTEreq SACTErsp SSYNmreq SSYNmrsp T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [4T55.225] p.20\fR .sp 1P .RT .ad b .RT .ce \fBH.T. [5T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(cont.)\fR .ce \fBSynchronization state table\fR .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ MIA p17 STA05B p17 STA05C p17 STA06 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ MIP p14 STA05B p14 STA05C p14 STA06 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ SACTEreq SACTErsp SSYNmreq SSYNmrsp T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p18&p21 MIA [25] STA09 p18&\*\|ip20&p21 MIA [25] STA10A T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [5T55.225] p.21\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [6T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(cont.)\fR .ce \fBSynchronization state table\fR .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p71 STA15B STA15D T{ SACTErsp PR\(hyMAA (1) AEA [14] [22] STA713 T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D SSYNmreq .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p15 STA15B STA15D T{ SSYNmrsp p18&\*\|ip20&p21 MIA [25] STA10B T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p18&p21 STA15B STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [6T55.225] p.22\fR .sp 1P .RT .ad b .RT .LP .rs .sp 18P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [7T55.225]\fR .ce TABLE\ A\(hy9/X.225 \fI(end)\fR .ce \fBSynchronization state table\fR .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p71 AE [13] [24] STA04B SACTErsp T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . SSYNmreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p15 MIP [24] STA713 SSYNmrsp . p18&p21 MIA [25] STA713 T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy9/X.225, [7T55.225] p.23\fR .sp 1P .RT .ad b .RT .LP .rs .sp 15P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T56.225]\fR .ce TABLE\ A\(hy10/X.225 .ce \fBResynchronization state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ PR\(hyRS STA01A TDISreq STA01 TDISreq STA01 [10] STA02A p10 STA15B STA15B STA15B RA STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ RS\(hya STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p10&\*\|ip34&p35 [19] SRSYNind(2) [16] STA11A p35 [19] SRSYNind(2) [16] STA11A p35 [19] SRSYNind(2) [16] STA11A RS\(hyr STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p10&\*\|ip34& p35&p32 SRSYNind [16] STA11A p32&p35 SRSYNind [16] STA11A p32&p35 SRSYNind [16] STA11A RS\(hys STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p10&\*\|ip34&p35 SRSYNind [16] STA11A p35 SRSYNind [16] STA11A p35 SRSYNind [16] STA11A SRSYNreq(a) . T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ . p28 PR\(hyRS(1) RS\(hya [16] STA05A T} SRSYNreq(r) SRSYNreq(s) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ . p28 PR\(hyRS(1) RS\(hys [16] STA05A T} SRSYNrsp .TE .nr PS 9 .RT .ad r \fBTableau A\(hy10/X.225, [1T56.225] p.24\fR .sp 1P .RT .ad b .RT .LP .rs .sp 8P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [2T56.225]\fR .ce TABLE\ A\(hy10/X.225 \fI(cont.)\fR .ce \fBResynchronization state table\fR .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ PR\(hyRS STA06 STA05B STA05C [10] STA06 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ RA p35&p49 SRSYNcnf [28] [11] STA713 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ RS\(hya \*\|ip24&p35 STA05A p24&p35 [19] SRSYNind(2) [16] STA11A p28 STA05B p28 STA05C \*\|ip24 STA05A [6] p24 [19] SRSYNind(2) [16] STA11A [6] T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ RS\(hyr \*\|ip24&p32&p35 STA05A p24&p32&p35 SRSYNind [16] STA11A p28 STA05B p28 STA05C \*\|ip24&p32 STA05A [6] p24&p32 SRSYNind [16] STA11A [6] T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ RS\(hys \*\|ip24&p35 STA05A p24&p35 SRSYNind [16] STA11A p28 STA05B p28 STA05C \*\|ip24 STA05A [6] p24 SRSYNind [16] STA11A [6] T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . SRSYNreq(a) .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p10&p28&\*\|ip34 PR\(hyRS(1) RS\(hya [16] STA05A SRSYNreq(r) T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p10&p25&\*\|ip34&p33 PR\(hyRS(1) RS\(hyr [16] STA05A SRSYNreq(s) T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p10&p25&\*\|ip34 PR\(hyRS(1) RS\(hys [16] STA05A SRSYNrsp T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy10/X.225, [2T56.225] p.25\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [3T56.225]\fR .ce TABLE\ A\(hy10/X.225 \fI(cont.)\fR .ce \fBResynchronization state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . PR\(hyRS STA15B STA15B .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ [10] STA15A . [10] STA15C RA T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p36&p49 SRSYNcnf [28] [11] STA713 [6] STA15D RS\(hya p35 [19] SRSYNind(2) [16] STA11A T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p29 [19] SRSYNind(2) [16] STA11A T} STA15D RS\(hyr .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p32&p29 SRSYNind [16] STA11A T} T{ STA15D RS\(hys p35 SRSYNind [16] STA11A T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . p29 SRSYNind [16] STA11A T{ STA15D SRSYNreq(a) p28 PR\(hyRS(1) RS\(hya [16] STA05A p28 PR\(hyRS(1) RS\(hya [16] STA05A p24 PR\(hyRS(1) RS\(hya [16] STA05A p28&p30 PR\(hyRS(1) RS\(hya [16] STA05A [6] p27&p28 PR\(hyRS(1) RS\(hya [16] STA06 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ STA15D SRSYNreq(r) p25&p33 PR\(hyRS(1) RS\(hyr [16] STA05A p25&p33 PR\(hyRS(1) RS\(hyr [16] STA05A p24&p33 PR\(hyRS(1) RS\(hyr [16] STA05A T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p25&p27&p33 PR\(hyRS(1) RS\(hyr [16] STA06 T} T{ STA15D SRSYNreq(s) p25 PR\(hyRS(1) RS\(hys [16] STA05A p25 PR\(hyRS(1) RS\(hys [16] STA05A p24 PR\(hyRS(1) RS\(hys [16] STA05A p28&p30 PR\(hyRS(1) RS\(hys [16] STA05A [6] p25&p27 PR\(hyRS(1) RS\(hys [16] STA06 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . STA15D SRSYNrsp .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p43 PR\(hyRA(1) RA [28] [11] STA713 T} STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy10/X.225, [3T56.225] p.26\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [4T56.225]\fR .ce TABLE\ A\(hy10/X.225 \fI(end)\fR .ce \fBResynchronization state table\fR .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ PR\(hyRS STA16 [10] STA18 STA15B STA15B p26 STA15B \*\|ip26 [10] STA713 RA STA16 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . RS\(hya STA16 .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p35 [19] SRSYNind(2) [16] STA11A p35 [19] SRSYNind(2) [16] STA11A p26&p35 [19] SRSYNind(2) [16] STA11A RS\(hyr STA16 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p32&p35 SRSYNind [16] STA11A p32&p35 SRSYNind [16] STA11A p32&p26&p35 SRSYNind [16] STA11A RS\(hys STA16 T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p35 SRSYNind [16] STA11A p35 SRSYNind [16] STA11A p26&p35 SRSYNind [16] STA11A SRSYNreq(a) T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p28 PR\(hyRS(1) RS\(hya [16] STA05A p29 PR\(hyRS(1) RS\(hya [16] STA05A SRSYNreq(r) T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p25&p33 PR\(hyRS(1) RS\(hyr [16] STA05A p25&p26&p33 PR\(hyRS(1) RS\(hyr [16] STA05A SRSYNreq(s) T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . T{ p25 PR\(hyRS(1) RS\(hys [16] STA05A p25&p26 PR\(hyRS(1) RS\(hys [16] STA05A SRSYNrsp T} .T& lw(42p) | lw(36p) | lw(42p) | lw(36p) | lw(36p) | lw(36p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy10/X.225, [4T56.225] p.27\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T57.225]\fR .ce TABLE\ A\(hy11/X.225 .ce \fBActivity interrupt and discard state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p38&p40 SACTDind [16] STA11C T} T{ ADA STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ AI STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p38&p40 SACTIind [16] STA11B T} T{ AIA STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p38 SACTIcnf [29] STA713 SACTDreq T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p34&p39 PR\(hyRS(1) AD [16] STA05C p39 PR\(hyRS(1) AD [16] STA05C T} SACTDrsp SACTIreq .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ p34&p39 PR\(hyRS(1) AI [16] STA05B p39 PR\(hyRS(1) AI [16] STA05B T} SACTIrsp .TE .nr PS 9 .RT .ad r \fBTableau A\(hy11/X.225, [1T57.225] p.28\fR .sp 1P .RT .ad b .RT .LP .rs .sp 13P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [2T57.225]\fR .ce TABLE\ A\(hy11/X.225 \fI(cont.)\fR .ce \fBActivity interrupt and discard state table\fR .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p37&p40 SACTDind [16] STA11C p38&p40 SACTDind [16] STA11C p38&p40 SACTDind [16] STA11C T} T{ ADA p38 SACTDcnf [29] STA713 T} .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . AI .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p37&p40 SACTIind [16] STA11B p38&p40 SACTIind [16] STA11B p38&p40 SACTIind [16] STA11B T} AIA .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . SACTDreq .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p34&p39 PR\(hyRS(1) AD [16] STA05C T} SACTDrsp .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . SACTIreq .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p34&p39 PR\(hyRS(1) AI [16] STA05B T} SACTIrsp .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ PR\(hyRA(1) AIA [30] STA713 T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy11/X.225, [2T57.225] p.29\fR .sp 1P .RT .ad b .RT .LP .rs .sp 12P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [3T57.225]\fR .ce TABLE\ A\(hy11/X.225 \fI(cont.)\fR .ce \fBActivity interrupt and discard state table\fR .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p37&p40 SACTDind [16] STA11C T} STA16 ADA .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p37&p41 SACTDcnf [29] STA713 [6] STA15D STA16 AI T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p37&p40 SACTIind [16] STA11B T} STA15D STA16 AIA .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p37&p42 SACTIcnf [29] STA713 [6] STA15D STA16 SACTDreq T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p34&p39 PR\(hyRS(1) AD [16] STA05C [6] p27&p34&p39 PR\(hyRS(1) AD [16] STA05C T} STA15D T{ SACTDrsp PR\(hyRA(1) ADA [30] STA713 T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D SACTIreq .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p34&p39 PR\(hyRS(1) AI [16] STA05B [6] p27&p34&p39 PR\(hyRS(1) AI [16] STA05B T} STA15D SACTIrsp .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy11/X.225, [3T57.225] p.30\fR .sp 1P .RT .ad b .RT .LP .rs .sp 8P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [4T57.225]\fR .ce TABLE\ A\(hy11/X.225 \fI(end)\fR .ce \fBActivity interrupt and discard state table\fR .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ AI p38&p40 SACTIind [16] STA11B p38&p40 SACTIind [16] STA11B p38&p40 SACTIind [16] STA11B AIA T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . SACTDreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p34&p11 PR\(hyRS(1) AD [16] STA05C p34&p39 PR\(hyRS(1) AD [16] STA05C SACTDrsp T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . SACTIreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p34&p11 PR\(hyRS(1) AI [16] STA05B p34&p39 PR\(hyRS(1) AI [16] STA05B SACTIrsp T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) . .TE .nr PS 9 .RT .ad r \fBTableau A\(hy11/X.225, [4T57.225] p.31\fR .sp 1P .RT .ad b .RT .LP .rs .sp 16P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [T58.225]\fR .ce TABLE\ A\(hy12/X.225 .ce \fBActivity start, resume and capability data state table\fR .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . T{ p44 SACTRind [12] [27] STA713 [6] AS STA01A TDISreq STA01 TDISreq STA01 p44 SACTSind [12] [26] STA15B STA15D STA16 T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . T{ p44 SACTSind [12] [26] STA713 [6] CD STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D STA16 T{ p46 SCDind STA22 CDA STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D STA16 SCDcnf STA713 SACTRreq .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D T{ p45 AR [12] [27] STA713 SACTSreq T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D T{ p45 AS [12] [26] STA713 SCDreq T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D p47 CD STA21 SCDrsp .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . STA15D CDA STA713 .TE .nr PS 9 .RT .ad r \fBTableau A\(hy12/X.225, [T58.225] p.32\fR .sp 1P .RT .ad b .RT .LP .rs .sp 12P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T59.225]\fR .ce TABLE\ A\(hy13/X.225 .ce \fBToken management and exceptions state table\fR .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . T{ p59 SGTind [11] STA04A p59 SGTind [11] STA04B p59 STA05A p59 STA05B GTA STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . T{ GTC STA01A TDISreq STA01 TDISreq STA01 T} .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . T{ PT STA01A TDISreq STA01 TDISreq STA01 p53 SPTind STA03 p53 SPTind STA04A p53 SPTind STA04B p53 STA05A p53 STA05B SCGreq T} .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . SGTreq .T& lw(32p) | lw(26p) | lw(20p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(26p) | lw(20p) . T{ p54 GT [11] STA04A p54 GT [11] STA04B T} SPTreq SUERreq .TE .nr PS 9 .RT .ad r \fBTableau A\(hy13/X.225, [1T59.225] p.33\fR .sp 1P .RT .ad b .RT .LP .rs .sp 6P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [2T59.225]\fR .ce TABLE\ A\(hy13/X.225 \fI(cont.)\fR .ce \fBToken management and exceptions state table\fR .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . ER p48 STA05C p48 STA06 .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . GT p59 STA05C p59 STA06 .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p59 SGTind [11] STA10A p59 SGTind [11] STA10B p59 SGTind [11] STA15A GTA T} .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . GTC .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . PT p53 STA05C p53 STA06 .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . p53 SPTind STA15A SCGreq .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . SGTreq .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p54 GT [11] STA10A p54 GT [11] STA10B p54 GT [11] STA15A SPTreq T} .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p53 PT STA09 p53 PT STA10A p53 PT STA10B T} SUERreq .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ p50 ED STA19 p50 ED STA19 p50 ED STA19 T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy13/X.225, [2T59.225] p.34\fR .sp 1P .RT .ad b .RT .LP .rs .sp 8P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [3T59.225]\fR .ce TABLE\ A\(hy13/X.225 \fI(cont.)\fR .ce \fBToken management and exceptions state table\fR .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p48 STA15C STA15D STA16 p50 SUERind STA19 ER .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . p48 STA15C STA15D STA16 T{ p50 SPERind STA19 GT p59 STA15B p59 STA15C STA15D STA16 T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ p60 SGTind [11] STA19 p61 SGTind [11] STA713 GTA T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D STA16 STA713 [6] GTC .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D STA16 T{ PT p53 STA15B p53 STA15C STA15D STA16 p53 SPTind STA18 p53 STA19 SCGreq T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D SGTreq p54 STA15B .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D SPTreq p53 STA15B .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D SUERreq p50 STA15B .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy13/X.225, [3T59.225] p.35\fR .sp 1P .RT .ad b .RT .LP .rs .sp 8P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [4T59.225]\fR .ce TABLE\ A\(hy13/X.225 \fI(end)\fR .ce \fBToken management and exceptions state table\fR .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p50 SUERind STA713 p51 SUERind STA20 ER T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p48 SPERind STA20 T{ p50 SPERind STA713 p51 SPERind STA20 GT p60 SGTind [11] STA20 p61 SGTind [11] STA713 p59 SGTind [11] STA21 T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p59 SGTind [11] STA713 GTA .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . GTC .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p62 SCGind GTA [11] STA713 PT p53 STA20 p53 SPTind STA21 T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p53 SPTind STA713 SCGreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p55 GTC [11] STA18 SGTreq p57 GT [11] STA20 p58 GT [11] STA713 T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p54 GT [11] STA713 SPTreq .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ p53 PT STA22 p53 PT STA713 SUERreq T} .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . p50 ED STA19 .TE .nr PS 9 .RT .ad r \fBTableau A\(hy13/X.225, [4T59.225] p.36\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T60.225]\fR .ce TABLE\ A\(hy14/X.225 .ce \fBConnection release state table\fR .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . T{ p69&\*\|ip01 SRELcnf+ [32] STA09 FN\(hynr STA01A TDISreq STA01 TDISreq STA01 \*\|ip65 SRELind [8] [18] STA09 p68 STA05A p68 STA06 T} .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . T{ FN\(hyr STA01A TDISreq STA01 TDISreq STA01 \*\|ip65&\*\|ip01&p16 SRELind [8] [18] STA09 p68&\*\|ip01&p16 STA05A T} .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . T{ NF STA01A TDISreq STA01 TDISreq STA01 p67 SRELcnf\(em STA713 T} .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . SRELreq .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . T{ p65 FN\(hynr [8] [18] STA09 SRELrsp+ T} .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . T{ \*\|ip66&p75 DN [4] STA16 p66 DN STA01C p69&p01 DN STA03 SRELrsp\(em T} .T& lw(33p) | lw(24p) | lw(27p) | lw(33p) | lw(30p) | lw(27p) | lw(27p) | lw(27p) . p67 NF STA713 .TE .nr PS 9 .RT .ad r \fBTableau A\(hy14/X.225, [1T60.225] p.37\fR .sp 1P .RT .ad b .RT .LP .rs .sp 7P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [2T60.225]\fR .ce TABLE\ A\(hy14/X.225 \fI(end)\fR .ce \fBConnection release state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ FN\(hynr . p68 STA15C STA15D STA16 p68 STA19 p68 STA20 p68 SRELind [8] STA09 FN\(hyr . p68&\*\|ip01&p16 STA15C . STA16 p68&\*\|ip01&p16 STA19 p68&\*\|ip01&p16 STA20 p68&\*\|ip01&p16 SRELind [9] STA09 NF p67 SRELcnf\(em STA15B T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . STA15D STA16 SRELreq p63 STA15B .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . STA15D T{ p63&\*\|ip64 FN\(hynr [8] STA03 p63&p64 FN\(hyr [7] STA03 SRELrsp+ T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . STA15D SRELrsp\(em .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . STA15D .TE .nr PS 9 .RT .ad r \fBTableau A\(hy14/X.225, [2T60.225] p.38\fR .sp 1P .RT .ad b .RT .LP .rs .sp 15P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [1T61.225]\fR .ce TABLE\ A\(hy15/X.225 .ce \fBAbort state table\fR .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . T{ AB\(hynr / / [3] TDISreq STA01 / / TDISreq STA01 TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 AB\(hyr / / [3] STA01C / / \*\|ip02 TDISreq STA01 p02 AA STA01C \*\|ip02 TDISreq STA01 p02 AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C PR\(hyAB / / / / / / TDISreq STA01 / / STA15D / / STA15D STA15D SUABreq T} .T& lw(27p) | lw(21p) | lw(21p) | lw(21p) | lw(28p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) | lw(22p) . TDISreq STA01 T{ \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A TDISind / / [3] STA01 SPABind STA01 STA01 STA01 SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 TIM / / TDISreq STA01 / / / / / / / / / / / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy15/X.225, [1T61.225] p.39\fR .sp 1P .RT .ad b .RT .LP .rs .sp 9P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [2T61.225]\fR .ce TABLE\ A\(hy15/X.225 \fI(cont.)\fR .ce \fBAbort state table\fR .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ AB\(hynr SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 AB\(hyr \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C T} .T& lw(36p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) | lw(35p) | lw(29p) . T{ \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C PR\(hyAB STA15D\fR STA15D\fR STA15D\fR STA15D\fR STA15D\fR STA15D \fR SUABreq \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A TDISind SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 TIM / / / / / / / / / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy15/X.225, [2T61.225] p.40\fR .sp 1P .RT .ad b .RT .LP .rs .sp 15P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [3T61.225]\fR .ce TABLE\ A\(hy15/X.225 \fI(cont.)\fR .ce \fBAbort state table\fR .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . .T& lw(36p) | lw(30p) | lw(36p) | lw(30p) | lw(30p) | lw(36p) | lw(30p) . T{ AB\(hynr SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 AB\(hyr \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C PR\(hyAB STA15D\fR STA15D\fR STA15D\fR STA15D\fR STA15D\fR STA15D \fR SUABreq \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A TDISind SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 TIM / / / / / / / / / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy15/X.225, [3T61.225] p.41\fR .sp 1P .RT .ad b .RT .LP .rs .sp 15P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [4T61.225]\fR .ce TABLE\ A\(hy15/X.225 \fI(cont.)\fR .ce \fBAbort state table\fR .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . [3] TDISreq STA01 T{ AB\(hynr SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 [3] TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 AB\(hyr T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ [3] TDISreq STA01 \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C PR\(hyAB STA15D\fR STA15D\fR STA15D\fR T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ [3] TDISreq STA01 STA15D\fR STA15D \fR SUABreq \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 [4] STA15D T} .T& lw(33p) | lw(27p) | lw(27p) | lw(27p) | lw(33p) | lw(27p) | lw(27p) | lw(27p) . T{ \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A TDISind SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 [3] STA01 SPABind STA01 SPABind STA01 TIM / / / / / / TDISreq STA01 TDISreq STA01 / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy15/X.225, [4T61.225] p.42\fR .sp 1P .RT .ad b .RT .LP .rs .sp 11P .ad r Blanc .ad b .RT .LP .bp .ce \fBH.T. [5T61.225]\fR .ce TABLE\ A\(hy15/X.225 \fI(end)\fR .ce \fBAbort state table\fR .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . .T& lw(42p) | lw(42p) | lw(42p) | lw(42p) | lw(42p) . T{ AB\(hynr SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 SxABind(3) TDISreq STA01 AB\(hyr \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C \*\|ip02 SxABind(3) TDISreq STA01 p02 SxABind(3) AA STA01C PR\(hyAB STA15D\fR STA15D\fR STA15D\fR STA15D \fR SUABreq \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A \*\|ip02 PR\(hyAB(4) AB\(hynr [4] STA16 p02 AB\(hyr [4] STA01A TDISind SPABind STA01 SPABind STA01 SPABind STA01 SPABind STA01 TIM / / / / / / / / T} .TE .nr PS 9 .RT .ad r \fBTableau A\(hy15/X.225, [5T61.225] p.43\fR .sp 1P .RT .ad b .RT .ce 1000 ANNEX\ B .ce 0 .ce 1000 (to Recommendation X.225) .sp 9p .RT .ce 0 .ce 1000 \fBRelationship to CCITT Recommendation T.62 encoding\fR .sp 1P .RT .ce 0 .PP This Recommendation has been designed to be compatible with Recommendation\ T.62. .sp 1P .RT .PP Table B\(hy1/X.225 shows the relationship between the Recommendation\ T.62 commands and responses and the SPDUs used in this Recommendation. .PP Table B\(hy2/X.225 shows the relationship between the Recommendation\ T.62 PGI and PI parameters and the PGI and PI parameters used in this Recommendation. .PP Annex C lists the PGIs and PIs which are not defined in this Recommendation, but are reserved as they are used in Recommendation\ T.62 for parameters relevant to higher layers than the session layer. Use of these PGIs and PIs is necessary for correct operation to Recommendation\ T.62. An implementation of the protocol specified in this Recommendation will need to be enhanced to take account of these PGI and PI units. .bp .RT .ce \fBH.T. [T62.225]\fR .ce TABLE\ B\(hy1/X.225 .ce \fBRelationship between T.62 commands and responses and X.225 SPDUs\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(24p) | cw(42p) | cw(42p) | cw(120p) . Code T.62 name SPDU Code SPDU name _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 13 CSS CN CONNECT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 16 xxxx OA OVERFLOW ACCEPT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 15 xxxx CDO CONNECT DATA OVERFLOW .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 14 RSSP AC ACCEPT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 12 RSSN RF REFUSE .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 9 CSE FN FINISH .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 10 RSEP DN DISCONNECT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 25 CSA AB ABORT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 26 RSAP AA ABORT ACCEPT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 1 CSUI\(hyCDUI DT DATA TRANSFER _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 2 RSUI PT PLEASE TOKENS .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 21 CSCC GTC GIVE TOKENS CONFIRM .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 22 RSCCP GTA GIVE TOKENS ACK .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 1 CSUI GT GIVE TOKENS _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 0 RSUI\(hyRDGR ER EXCEPTION REPORT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 48 RSUI\(hyRDPBN ED EXCEPTION DATA _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 33 CSTD TD TYPED DATA _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 8 xxxx NF NOT FINISHED _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 49 CSUI\(hyCDPB MIP MINOR SYNC POINT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 50 RSUI\(hyRDPBP MIA MINOR SYNC ACK _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 41 CSUI\(hyCDE MAP MAJOR SYNC POINT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 42 RSUI\(hyRDEP MAA MAJOR SYNC ACK .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 7 xxxx PR PREPARE _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 53 xxxx RS RESYNCHRONIZE .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 34 xxxx RA RESYNCHRONIZE ACK _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . \ 5 xxxx EX EXPEDITED DATA _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 45 CSUI\(hyCDS AS ACTIVITY START .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 29 CSUI\(hyCDC AR ACTIVITY RESUME .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 25 CSUI\(hyCDR AI ACTIVITY INTERRUPT .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 26 RSUI\(hyRDRP AIA ACTIVITY INTERRUPT ACK .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 57 CSUI\(hyCDD AD ACTIVITY DISCARD .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 58 RSUI\(hyRDDP ADA ACTIVITY DISCARD ACK .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 41 CSUI\(hyCDE AE ACTIVITY END \fR .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 42 RSUI\(hyRDEP AEA ACTIVITY END ACK _ .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 61 CSUI\(hyCDCL CD CAPABILITY DATA .T& cw(24p) | lw(42p) | lw(42p) | lw(120p) . 62 RSUI\(hyRDCLP CDA CAPABILITY DATA ACK _ .TE .nr PS 9 .RT .ad r \fBTableau B\(hy1/X.225, [T62.225] p.44\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [1T63.225]\fR .ce TABLE\ B\(hy2/X.225 .ce \fBRelationship between Recommendation T.62 PGI/PI and .ce Recommendation X.225 parameters\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(96p) | cw(36p) | cw(96p) . T.62 parameters code X.225 parameters _ .T& lw(96p) | cw(36p) | cw(96p) . PGI .T& lw(96p) | cw(36p) | lw(96p) . Reserved for extension \ 0 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Session reference \ 1 Connection Identifier .T& lw(96p) | cw(36p) | lw(96p) . T{ Non\(hybasic session capabilities T} \ 2 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . \ 3 .T& lw(96p) | cw(36p) | lw(96p) . \ 4 .T& lw(96p) | cw(36p) | lw(96p) . \ 5 Connect/Accept Item .T& lw(96p) | cw(36p) | lw(96p) . \ 6 .T& lw(96p) | cw(36p) | lw(96p) . \ 7 _ .T& lw(96p) | cw(36p) | lw(96p) . PI .T& lw(96p) | cw(36p) | lw(96p) . Service identifier \ 8 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . T{ Terminal identifier (called terminal) T} \ 9 Called SS\(hyuser Ref. .T& lw(96p) | cw(36p) | lw(96p) . T{ Terminal identifier (calling terminal) T} 10 Calling SS\(hyuser Ref. .T& lw(96p) | cw(36p) | lw(96p) . Date and time 11 Common Reference .T& lw(96p) | cw(36p) | lw(96p) . T{ Additional session reference number T} 12 Additional Ref. Info. .T& lw(96p) | cw(36p) | lw(96p) . T{ Miscellaneous session capabilities T} 13 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Window size 14 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . 15 Sync Type Item .T& lw(96p) | cw(36p) | lw(96p) . Session control functions 16 Token Item .T& lw(96p) | cw(36p) | lw(96p) . Session termination parameter 17 Transport Disconnect .T& lw(96p) | cw(36p) | lw(96p) . Inactivity timer 18 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . 19 Protocol options .T& lw(96p) | cw(36p) | lw(96p) . Session service functions 20 Session Requirements .T& lw(96p) | cw(36p) | lw(96p) . 21 TSDU Maximum Size .T& lw(96p) | cw(36p) | lw(96p) . 22 Version number .T& lw(96p) | cw(36p) | lw(96p) . 23 Initial Serial Number .T& lw(96p) | cw(36p) | lw(96p) . 24 Prepare Type .T& lw(96p) | cw(36p) | lw(96p) . 25 Enclosure Item .T& lw(96p) | cw(36p) | lw(96p) . 26 Token Setting Item .T& lw(96p) | cw(36p) | lw(96p) . 27 Resync Type .T& lw(96p) | cw(36p) | lw(96p) . Initiator's reference number 28 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Acceptor's reference number 29 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . T{ Reactivation/transaction indication T} 30 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Suspend reject reason 31 See Table C\(hy1/X.225 _ .T& lw(96p) | cw(36p) | lw(96p) . PGI .T& lw(96p) | cw(36p) | lw(96p) . Reserved for extension 32 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Document linking 33 Linking Information .T& lw(96p) | cw(36p) | lw(96p) . 34 .T& lw(96p) | cw(36p) | lw(96p) . 35 .T& lw(96p) | cw(36p) | lw(96p) . 36 .T& lw(96p) | cw(36p) | lw(96p) . 37 .T& lw(96p) | cw(36p) | lw(96p) . 38 .T& lw(96p) | cw(36p) | lw(96p) . 39 _ .TE .nr PS 9 .RT .ad r \fBTableau B\(hy2/X.225, [1T63.225] p.45\fR .sp 1P .RT .ad b .RT .LP .bp .ce \fBH.T. [2T63.225]\fR .ce TABLE\ B\(hy2/X.225 \fI(cont.)\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(96p) | cw(36p) | cw(96p) . T.62 parameters code X.225 parameters _ .T& lw(96p) | cw(36p) | cw(96p) . PI .T& lw(96p) | cw(36p) | lw(96p) . T{ Service interworking identifier T} 40 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Document reference number 41 Activity identifier .T& lw(96p) | cw(36p) | lw(96p) . Checkpoint reference number 42 Serial number .T& lw(96p) | cw(36p) | lw(96p) . Reserved 43 .T& lw(96p) | cw(36p) | lw(96p) . Acceptance of CDCL parameters 44 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Storage capacity negotiation 45 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Receiving ability jeopardized 46 User data (in MIA SPDU) .T& lw(96p) | cw(36p) | lw(96p) . Reserved 47 .T& lw(96p) | cw(36p) | lw(96p) . Document type identifier 48 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Reflect parameter values 49 Reflect parameter values .T& lw(96p) | cw(36p) | lw(96p) . Reason (session and document) 50 Reason code .T& lw(96p) | cw(36p) | lw(96p) . 51 Calling session selector .T& lw(96p) | cw(36p) | lw(96p) . 52 T{ Called/Responding session selector T} .T& lw(96p) | cw(36p) | lw(96p) . 53 .T& lw(96p) | cw(36p) | lw(96p) . 54 .T& lw(96p) | cw(36p) | lw(96p) . 55 .T& lw(96p) | cw(36p) | lw(96p) . 56 .T& lw(96p) | cw(36p) | lw(96p) . 57 .T& lw(96p) | cw(36p) | lw(96p) . 58 .T& lw(96p) | cw(36p) | lw(96p) . 59 .T& lw(96p) | cw(36p) | lw(96p) . 60 Data overflow .T& lw(96p) | cw(36p) | lw(96p) . 61 .T& lw(96p) | cw(36p) | lw(96p) . 62 .T& lw(96p) | cw(36p) | lw(96p) . 63 _ .T& lw(96p) | cw(36p) | lw(96p) . PGI .T& lw(96p) | cw(36p) | lw(96p) . Reserved for extension 64 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . T{ Nonbasic teletex terminal capabilities T} 65 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . 66 .T& lw(96p) | cw(36p) | lw(96p) . 67 .T& lw(96p) | cw(36p) | lw(96p) . 68 .T& lw(96p) | cw(36p) | lw(96p) . 69 .T& lw(96p) | cw(36p) | lw(96p) . 70 .T& lw(96p) | cw(36p) | lw(96p) . 71 _ .T& lw(96p) | cw(36p) | lw(96p) . PI .T& lw(96p) | cw(36p) | lw(96p) . Graphic character set 72 T{ See Table C\(hy1/X.225 \fR T} .T& lw(96p) | cw(36p) | lw(96p) . Control character set 73 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . Teletex page format 74 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . T{ Miscellaneous teletex terminal capabilities T} 75 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . 76 .T& lw(96p) | cw(36p) | lw(96p) . T{ Number of dots for character box height T} 77 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . T{ Number of dots for character box width T} 78 See Table C\(hy1/X.225 .T& lw(96p) | cw(36p) | lw(96p) . 79 _ .T& lw(96p) | cw(36p) | lw(96p) . PGI .T& lw(96p) | cw(36p) | lw(96p) . 192 .T& lw(96p) | cw(36p) | lw(96p) . Session user data 193 User data .T& lw(96p) | cw(36p) | lw(96p) . 194 Extended User Data _ .TE .nr PS 9 .RT .ad r \fBTableau B\(hy2/X.225, [2T63.225] p.46 .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ C .ce 0 .ce 1000 (to Recommendation X.225) .sp 9p .RT .ce 0 .ce 1000 \fBPGIs and PIs reserved for use by Recommendation\ T.62\fR .sp 1P .RT .ce 0 .PP Table C\(hy1/X.225 lists the PGIs and PIs which are not defined in this Recommendation, but which are reserved as they are used in Recommendation\ T.62 for parameters that are relevant to higher layers than the session layer. .sp 1P .RT .LP .sp 4 .ce \fBH.T. [T64.225]\fR .ce TABLE\ C\(hy1/X.225 .ce \fBPGIs and PIs reserved for use by Recommendation T.62\fR .ps 9 .vs 11 .nr VS 11 .nr PS 9 .TS center box; cw(36p) | lw(192p) . PGI .T& cw(36p) | lw(192p) . \ 0 Reserved for extension .T& cw(36p) | lw(192p) . \ 1 T{ Non\(hybasic session capabilities T} _ .T& cw(36p) | lw(192p) . PI .T& cw(36p) | lw(192p) . \ 8 Service identifier .T& cw(36p) | lw(192p) . 13 T{ Miscellaneous session capabilities T} .T& cw(36p) | lw(192p) . 14 Window size .T& cw(36p) | lw(192p) . 18 Inactivity timer .T& cw(36p) | lw(192p) . 28 Initiator's reference number .T& cw(36p) | lw(192p) . 29 Acceptor's reference number .T& cw(36p) | lw(192p) . 30 T{ Reactivation/transaction indication T} .T& cw(36p) | lw(192p) . 31 Suspend reject reason _ .T& cw(36p) | lw(192p) . PGI .T& cw(36p) | lw(192p) . 32 Reserved for extension _ .T& cw(36p) | lw(192p) . PI .T& cw(36p) | lw(192p) . 40 T{ Service interworking identifier T} .T& cw(36p) | lw(192p) . 44 Acceptance of CDCL parameters .T& cw(36p) | lw(192p) . 45 Storage capacity negotiation .T& cw(36p) | lw(192p) . 48 Document type identifier _ .T& cw(36p) | lw(192p) . PGI .T& cw(36p) | lw(192p) . 64 Reserved for extension .T& cw(36p) | lw(192p) . 65 T{ Non\(hybasic teletex terminal capabilities T} _ .T& cw(36p) | lw(192p) . PI .T& cw(36p) | lw(192p) . 72 Graphic character set .T& cw(36p) | lw(192p) . 73 Control character set .T& cw(36p) | lw(192p) . 74 Teletex page format .T& cw(36p) | lw(192p) . 75 T{ Miscellaneous teletex terminal capabilities T} .T& cw(36p) | lw(192p) . 77 T{ Number of dots for character box height T} .T& cw(36p) | lw(192p) . 78 T{ Number of dots for character box width T} _ .TE .nr PS 9 .RT .ad r \fBTableau C\(hy1/X.225, [T64.225] p.47 .sp 1P .RT .ad b .RT .LP .bp .ce 1000 ANNEX\ D .ce 0 .ce 1000 (to Recommendation X.225) .sp 9p .RT .ce 0 .ce 1000 \fBCompatibility between protocol version 1 and protocol version 2\fR .sp 1P .RT .ce 0 .PP Protocol version 2 of the Session Protocol is a superset of protocol version 1 (both of which are specified in this Recommendation). Protocol version\ 1 of the Session Protocol imposes restrictions on the length of user data fields. Protocol version\ 2 removes those length restrictions. .sp 1P .RT .PP An implementation of the session protocol may limit the length of user data supported, based on the requirements of its SS\(hyuser or protocol version supported. Any such limitation is stated in the Protocol Implementation Conformance Statement. If no user of a session implementation requires more than 10k of user data during connection establishment, the implementation need not be able to send the CDO\ SPDU or receive the OA\ SPDU. .PP Implementations of protocol version 2 can interwork with implementations of protocol version\ 1 only by imposing a number of restrictions (all of which are valid, in terms of the conformance statement). These restrictions are: .RT .LP a) User Data parameter value in the ABORT SPDU shall not exceed 9\ octets. .LP b) Reason Code parameter value in the REFUSE SPDU shall not exceed 513\ octets. .LP c) The User Data PGI unit shall not be present in GIVE TOKENS, GIVE TOKENS CONFIRM, ACTIVITY INTERRUPT, ACTIVITY INTERRUPT ACK, ACTIVITY DISCARD and ACTIVITY DISCARD ACK\ SPDUs. The User Data PGI unit in all other SPDUs shall not exceed 512\ octets. .LP d) Protocol version 1 shall be proposed in the CONNECT SPDU. In this case the Extended User Data parameter and Data Overflow parameter in the CONNECT\ SPDU shall not be present. .LP \fINote\fR \ \(em\ Protocol version 2 may also be proposed, but to operate validly with a protocol version\ 1 only implementation, protocol version\ 1 shall be selected. .PP As a consequence of protocol version 1 being selected: .LP e) segmenting, as specified in \(sc 6.3.5\ b) does not apply. Only data SSDUs and typed data SSDUs may be segmented; .LP f ) the OVERFLOW ACCEPT SPDU and CONNECT DATA OVERFLOW SPDU are not used. .LP \fINote\fR \ \(em\ Implementations of the earlier edition of this Recommendation which specified protocol version\ 1 can upgrade to and claim conformance with this edition of this Recommendation by stating, in their Protocol Implementation Conformance Statement, the restrictions specified in\ a) to\ c) above; and by conforming to the specified procedure for rejecting SPDUs with \*Qto much\*U user data (see \(sc\ A.4.3.1.2) (note that this requires that the implemantation recognises the Extended User Data parameter in the CONNECT SPDU and the Enclosure Item in the ABORT\ SPDU). This is a minimal implementation of protocol version\ 2 and will not satisfy the requirements of some\ ASEs. \v'6p' .ce 1000 APPENDIX\ I .ce 0 .ce 1000 (to Recommendation X.225) .sp 9p .RT .ce 0 .ce 1000 \fBDifferences between Recommendation X.225\fR .sp 1P .RT .ce 0 .sp 1P .ce 1000 \fBand ISO International Standard 8327\fR .ce 0 .sp 1P .PP I.1 In ISO 8327 the last sentence in the second paragraph of A.1 states \*QIn case of arbitration or dispute this annex takes precedence over clause\ 7\*U. This statement is not included in this Recommendation. .sp 1P .RT .LP .bp