|
BCC
3G TS 24.069 version 3.1.0
The Broadcast Call Control (BCC) protocol
is used by the Voice Group Call Service (VGCS) on the radio
interface. It is one of the Connection Management (CM) sublayer
protocols (see GSM 04.07).
Generally a number of mobiles stations
(MS) participate in a broadcast call. Consequently, there is
generally more than one MS with a BCC entity engaged in the
same broadcast call, and there is one BCC entity in the network
engaged in that broadcast call.
The MS ignores BCC messages sent in
unacknowledged mode and which specify as destination a mobile
identity which is not a mobile identity of that MS. Higher layers
and the MM sub-layer decide when to accept parallel BCC transactions
and when/whether to accept BCC transactions in parallel to other
CM transactions.
The broadcast call may be initiated
by a mobile user or by a dispatcher. The originator of the BCC
transaction chooses the Transaction Identifier (TI).
The call control entities are described
as communicating finite state machines which exchange messages
across the radio interface and communicate internally with other
protocol (sub)layers. In particular, the BCC protocol uses the
MM and RR sublayer specified in GSM 04.08. The network should
apply supervisory functions to verify that the BCC procedures
are progressing and if not, take appropriate means to resolve
the problems.
The elementary procedures in the BCC
include:
- Broadcast call establishment procedures,
- Broadcast call termination procedures
- Broadcast call information phase
procedures
- Various miscellaneous procedures.
All messages have the following header:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octet |
| Transaction
identifier |
Protocol
discriminator |
1 |
| Message
type |
2 |
| Information
elements |
3-n |
| BCC
beader structure |
. |
Protocol discriminator
The protocol discriminator specifies
the message being transferred
Transaction identifier
Distinguishes multiple parallel activities (transactions)
within one mobile station. The format of the transaction identifier
is as follows:
| 8 |
7 |
6 |
5 |
| TI flag |
TI
value |
| Transaction
identifier |
TI flag
Identifies who allocated the TI value for this transaction.
The purpose of the TI flag is to resolve simultaneous attempts
to allocate the same TI value.
TI value
The side of the interface initiating a transaction assigns
TI values. At the beginning of a transaction, a free TI value
is chosen and assigned to this transaction. It then remains
fixed for the lifetime of the transaction. After a transaction
ends, the associated TI value is free and may be reassigned
to a later transaction. Two identical transaction identifier
values may be used when each value pertains to a transaction
originated at opposite ends of the interface.
Message type
The message type defines the function of each BCC message.
The message type defines the function of each BCC message. The
following message types exist:
| 0x110001 |
IMMEDIATE SETUP |
| 0x110010 |
SETUP |
| 0x110011 |
CONNECT |
| 0x110100 |
TERMINATION |
| 0x110101 |
TERMINATION REQUEST |
| 0x110110 |
TERMINATION REJECT |
| 0x111000 |
STATUS |
| 0x111001 |
GET STATUS |
| 0x111010 |
SET PARAMETER |
Information elements
Each information element has a name which is coded as
a single octet. The length of an information element may be
fixed or variable and a length indicator for each one may be
included.
Interested in more details about testing
this protocol?
BSSAP+
http://www.etsi.org/ GSM 09.18 version 7.1.0
release 1998
BSSAP+ defines use of mobile resources when
a mobile station supports both GSM circuit switched services
and GSM packet switched services. It defines procedures used
on the Serving GPRS Support Node (SGSN) to Visitors Location
Register (VLR) for interoperability between circuit and packet
switched services. Layer 3 messages on the Gs interface are
defined.
| BSSAP+ |
|
BSSAP+ |
| SCCP |
|
SCCP |
| MTP L3 |
|
MTP L3 |
| MTP L2 |
|
MTP L2 |
| L1 |
|
L1 |
| SGSN |
Gs |
MSC/VLR |
| BSSAP+
protocol layer structure over Gs interface |
The Gs interface connects the databases
in the MSC/VLR and the SGSN. The procedures the of BSSAP+ protocol
are used to co-ordinate the location information of MSs that
are IMSI attached to both GPRS and non-GPRS services. The Gs
interface is also used to convey some circuit switched related
procedures via the SGSN.
The basis for the interworking
between a VLR and an SGSN is the existence of an association
between those entities per MS. An association consists of the
SGSN storing the number of the VLR serving the MS for circuit
switched services and the VLR storing the number of the SGSN
serving the MS for packet switched services. The association
is only applicable to MSs in class-A mode of operation and MSs
in class-B mode of operation.
All the messages in BSSAP+
use the SCCP class 0 connectionless service.
When the return option
in SCCP is used and the sender receives an N_NOTICE indication
from SCCP, the sending entity reports to the Operation and Maintenance
system (see ITU-T Q.714).
The behaviour of the VLR
and the SGSN entities related to the Gs interface are defined
by the state of the association for an MS. Individual states
per association, i.e. per MS in class-A mode of operation and
MS in class-B mode of operation, are held at both the VLR and
the SGSN.
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octet |
| Message
type |
1 |
| Information
elements |
2-n |
| BSSAP+
beader structure |
. |
The message type uniquely identifies
the message being sent. The following BSSAP+ message types exist:
| Value |
Message type |
| 00000000 |
Unassigned: treated as an unknown
Message type. |
| 00000001 |
BSSAP+-PAGING-REQUEST. |
| 00000010 |
BSSAP+-PAGING-REJECT |
| 00000011 |
|
| to |
|
| 00001000 |
Unassigned: treated as an unknown
Message type. |
| 00001001 |
00001001BSSAP+-LOCATION-UPDATE-REQUEST. |
| 00001010 |
BSSAP+-LOCATION-UPDATE-ACCEPT. |
| 00001011 |
BSSAP+-LOCATION-UPDATE-REJECT. |
| 00001100 |
BSSAP+-TMSI-REALLOCATION-COMPLETE. |
| 00001101 |
BSSAP+-ALERT-REQUEST. |
| 00001110 |
BSSAP+-ALERT-ACK. |
| 00001111 |
BSSAP+-ALERT-REJECT. |
| 00010000 |
BSSAP+-MS-ACTIVITY-INDICATION. |
| 00010001 |
BSSAP+-GPRS-DETACH-INDICATION. |
| 00010010 |
BSSAP+-GPRS-DETACH-ACK. |
| 00010011 |
BSSAP+-IMSI-DETACH-INDICATION. |
| 00010100 |
BSSAP+-IMSI-DETACH-ACK. |
| 00010101 |
BSSAP+-RESET-INDICATION. |
| 00010110 |
BSSAP+-RESET-ACK. |
| 00010111 |
BSSAP+-MS-INFORMATION-REQUEST. |
| 00011000 |
BSSAP+-MS-INFORMATION-RESPONSE. |
| 00011001 |
Unassigned: treated as an unknown
Message type. |
| 00011010 |
BSSAP+-MM-INFORMATION-REQUEST. |
| 00011101 |
BSSAP+-MOBILE-STATUS. |
| 00011110 |
Unassigned: treated as an unknown
Message type. |
| 00011111 |
BSSAP+-MS-UNREACHABLE. |
Each message type has specific information
elements
| 00000001 |
IMSI. |
| 00000010 |
VLR number. |
| 00000011 |
TMSI. |
| 00000100 |
Location area identifier. |
| 00000101 |
Channel Needed. |
| 00000110 |
eMLPP Priority. |
| 00000111 |
Unassigned: treated as an unknown
IEI. |
| 00001000 |
Gs cause. |
| 00001001 |
SGSN number. |
| 00001010 |
GPRS location update type. |
| 00001011 |
Unassigned: treated as an unknown
IEI. |
| 00001100 |
Unassigned: treated as an unknown
IEI. |
| 00001101 |
Mobile station classmark 1. |
| 00001110 |
Mobile identity. |
| 00001111 |
Reject cause. |
| 00010000 |
IMSI detach from GPRS service
type. |
| 00010001 |
IMSI detach from non-GPRS service
type. |
| 00010010 |
Information requested. |
| 00010011 |
PTMSI. |
| 00010100 |
IMEI. |
| 00010101 |
IMEISV. |
| 00010110 |
Unassigned: treated as an unknown
IEI. |
| 00010111 |
MM information. |
| 00011000 |
Cell Global Identity. |
| 00011001 |
Location information age. |
| 00011010 |
Mobile station state. |
| 00011011 |
Erroneous message. |
00011100
|
|
to
|
|
| 11111111 |
Unassigned: treated as an unknown
IEI. |
Interested in more details about testing
this protocol?
BSSGP
GSM 08.18 version 6.1.0 http://www.etsi.fr
The NS transports BSS (base station system)
GPRS protocol PDUs between a BSS and an SGSN (serving GPRS support
node). The primary functions of the BSSGP include:
- Provision by an SGSN to a BSS of radio
related information used by the RLC/MAC function (in the downlink).
- Provision by a BSS to an SGSN of radio
related information derived from the RLC/MAC function (In
the uplink).
- Provision of functionality to enable two
physically distinct nodes, an SGSN and a BSS, to operate node
management control functions.
BSSGP PDUs are of the following format:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octets |
PDU type |
1 |
Other Information Elements |
2-n |
NS
PDU structure |
|
Interested in more
details about testing this protocol?
GCC
3G TS 24.068 version 3.1.0
The Group Call Control (GCC) protocol
is used by the Voice Group Call Service (VGCS) on the radio
interface within the 3GPP system. It is one of the Connection
Management (CM) sublayer protocols (see GSM 04.07).
Generally a number of mobiles stations
(MS) participate in a group call. Consequently, there is in
general more than one MS with a GCC entity engaged in the same
group call, and there is one GCC entity in the network engaged
in that group call.
The MS ignores GCC messages sent in
unacknowledged mode and which specify as destination a mobile
identity which is not a mobile identity of that MS. Higher layers
and the MM sub-layer decide when to accept parallel GCC transactions
and when/whether to accept GCC transactions in parallel to other
CM transactions.
The group call may be initiated by
a mobile user or by a dispatcher. In certain situations, a MS
assumes to be the originator of a group call without being the
originator. The originator of the GCC transaction chooses the
Transaction Identifier (TI).
The call control entities are described
as communicating finite state machines which exchange messages
across the radio interface and communicate internally with other
protocol (sub) layers. In particular, the GCC protocol uses
the MM and RR sublayer specified in GSM 04.08. The network should
apply supervisory functions to verify that the GCC procedures
are progressing and if not, take appropriate means to resolve
the problems.
The elementary procedures in the GCC
include:
- Group call establishment procedures,
- Group call termination procedures
- Call information phase procedures
- Various miscellaneous procedures.
All messages have the following header:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octet |
| Transaction
identifier |
Protocol
discriminator |
1 |
| Message
type |
2 |
| Information
elements |
3-n |
| GCC
beader structure |
. |
Protocol discriminator
The protocol discriminator specifies
the message being transferred
Transaction identifier
Distinguishes multiple parallel activities (transactions)
within one mobile station. The format of the transaction identifier
is as follows:
| 8 |
7 |
6 |
5 |
| TI flag |
TI
value |
| Transaction
identifier |
TI flag
Identifies who allocated the TI value for this transaction.
The purpose of the TI flag is to resolve simultaneous attempts
to allocate the same TI value.
TI value
The side of the interface initiating a transaction assigns
TI values. At the beginning of a transaction, a free TI value
is chosen and assigned to this transaction. It then remains
fixed for the lifetime of the transaction. After a transaction
ends, the associated TI value is free and may be reassigned
to a later transaction. Two identical transaction identifier
values may be used when each value pertains to a transaction
originated at opposite ends of the interface.
Message type
The message type defines the function of each GCC message.
The following message types exist:
| 0x110001 |
IMMEDIATE SETUP |
| 0x110010 |
SETUP |
| 0x110011 |
CONNECT |
| 0x1100100 |
TERMINATION |
| 0x110101 |
TERMINATION REQUEST |
| 0x110110 |
TERMINATION REJECT |
| 0x111000 |
STATUS |
| 0x111001 |
GET STATUS |
| 0x111010 |
SET PARAMETER |
Information elements
Each information element has a name which is coded as
a single octet. The length of an information element may be
fixed or variable and a length indicator for each one may be
included.
Interested in more details about testing
this protocol?
GMM
GSM 04.08 http://www.etsi.org
GPRS uses the GSM MM (Mobility Management)
protocol. Here it is known as the GPRS MM protocol (GMM). The
main function of the MM sub-layer is to support the mobility
of user terminals, for instance, informing the network of its
present location and providing user identity confidentiality.
A further function of the GMM sub-layer is to provide connection
management services to the different entities of the upper Connection
Management (CM) sub-layer.
The format of the header is shown in
the following illustration:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octet |
| Protocol
discriminator |
Skip
indicator |
1 |
| Message
type |
2 |
| Information
elements |
3-n |
| GMM
beader structure |
. |
Protocol discriminator
1000 identifies the GMM protocol.
Skip indicator
The value of this field is 0000.
Message type
Uniquely defines the function and format of each GMM
message. The message type is mandatory for all messages. Bit
8 is reserved for possible future use as an extension bit. Bit
7 is reserved for the send sequence number in messages sent
from the mobile station. GMM message types may be:
| 0 0 0 0 0 0 0 1 |
Attach request |
| 0 0 0 0 0 0 1 0 |
Attach accept |
| 0 0 0 0 0 0 1 1 |
Attach complete |
| 0 0 0 0 0 1 0 0 |
Attach reject |
| 0 0 0 0 0 1 0 1 |
Detach request |
| 0 0 0 0 0 1 1 0 |
Detach accept |
| 0 0 0 0 1 0 0 0 |
Routing area update request |
| 0 0 0 0 1 0 0 1 |
Routing area update accept |
| 0 0 0 0 1 0 1 0 |
Routing area update complete |
| 0 0 0 0 1 0 1 1 |
Routing area update reject |
| 0 0 0 1 0 0 0 0 |
P-TMSI reallocation command |
| 0 0 0 1 0 0 0 1 |
P-TMSI reallocation complete |
| 0 0 0 1 0 0 1 0 |
Authentication and ciphering req |
| 0 0 0 1 0 0 1 1 |
Authentication and ciphering resp |
| 0 0 0 1 0 1 0 0 |
Authentication and ciphering rej |
| 0 0 0 1 0 1 0 1 |
Identity request |
| 0 0 0 1 0 1 1 0 |
Identity response |
| 0 0 1 0 0 0 0 0 |
GMM status |
| 0 0 1 0 0 0 0 1 |
GMM information |
|
|
Information elements
Various information elements.
Interested in more details about testing
this protocol?
GSM
GSM 04.08
http://www.etsi.org
The main function of the GPRS session
management (SM) is to support PDP context handling of the user
terminal. The SM comprises procedures for: identified PDP context
activation, deactivation and modification, and anonymous PDP
context activation and deactivation.
The format of the header is shown in
the following illustration:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octet |
| Protocol
discriminator |
Skip
indicator |
1 |
| Message
type |
2 |
| Information
elements |
3-n |
| GSM
beader structure |
. |
Protocol discriminator
1010 identifies the GSM protocol.
Skip indicator
The value of this field is 0000.
Message type
Uniquely defines the function and format of each GSM
message. The message type is mandatory for all messages. Bit
8 is reserved for possible future use as an extension bit. Bit
7 is reserved for the send sequence number in messages sent
from the mobile station. GSM message types may be:
| 0 1 x x x x x x |
Session management messages |
| 0 1 0 0 0 0 0 1 |
Activate PDP context request |
| 0 1 0 0 0 0 1 0 |
Activate PDP context accept |
| 0 1 0 0 0 0 1 1 |
Activate PDP context reject |
| 0 1 0 0 0 1 0 0 |
Request PDP context activation |
| 0 1 0 0 0 1 0 1 |
Request PDP context activation
rej. |
| 0 1 0 0 0 1 1 0 |
Deactivate PDP context request |
| 0 1 0 0 0 1 1 1 |
Deactivate PDP context accept |
| 0 1 0 0 1 0 0 0 |
Modify PDP context request |
| 0 1 0 0 1 0 0 1 |
Modify PDP context accept |
| 0 1 0 1 0 0 0 0 |
Activate AA PDP context request |
| 0 1 0 1 0 0 0 1 |
Activate AA PDP context accept |
| 0 1 0 1 0 0 1 0 |
Activate AA PDP context reject |
| 0 1 0 1 0 0 1 1 |
Deactivate AA PDP context request |
| 0 1 0 1 0 1 0 0 |
Deactivate AA PDP context accept |
| 0 1 0 1 0 1 0 1 |
SM Status |
Information elements
Various information elements.
Interested in more details about testing
this protocol?
GTP
specifies a tunnel control and management
protocol which allows the SGSN to provide GPRS network access
for an MS. Signalling is used to create, modify and delete tunnels.
In the transmission plane, GTP uses a tunnelling mechanism to
provide a service for carrying user data packets. The choice
of path is dependent on whether the user data to be tunnelled
requires a reliable link or not.
The GTP protocol is implemented only
by SGSNs and GGSNs. No other systems need to be aware of GTP.
GPRS MSs are connected to a SGSN without being aware of GTP.
It is assumed that there will be a many-to-many relationship
between SGSNs and GGSNs. An SGSN may provide service to many
GGSNs. A single GGSN may associate with many SGSNs to deliver
traffic to a large number of geographically diverse mobile stations.
The GTP header is a fixed format 20
octet header used for all GTP messages.
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octets |
Version |
PT |
Spare ' 1 1 1 ' |
SNN |
1 |
Message
type |
2 |
Length |
3-4 |
Sequence Number |
5-6 |
Flow
label |
7-8 |
SNDCP N-PDULLC Number |
9 |
| |
|
|
|
|
|
|
|
|
Spare ' 1 1 1 1 1 1 1
1 ' |
10 |
Spare ' 1 1 1 1 1 1 1
1 ' |
11 |
Spare ' 1 1 1 1 1 1 1
1 ' |
12 |
TID |
13-20 |
|
|
Version
Set to 0 to indicate the
first version of GTP
Reserved
Reserved bits for future
use, set to 1.
LFN
Flag indicating whether
the LLC frame number is included or not.
Message Type
Type of GTP message.
Length
Indicates the length in octets of the GTP message (G-PDU).
Sequence number
Transaction identity for
signalling messages and an increasing sequence number for tunnelled
T-PDUs.
Flow label
Identifies unambiguously
a GTP flow.
LLC frame number
Used at the Inter SGSN
Routing Update procedure to coordinate the data tranmsission
on the link layer between the MS and the SGSN.
x
Spare bits x indicate
the unused bits which are set to 0 by the sending side and are
ignored by the receiving side.
FN
Continuation of LLC frame
number.
TID
Tunnel identifier that
points out MM and PDP contexts.The format of the TID is as follows:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octets |
MCC
digit 2 |
MCC
digit 1 |
1 |
MNC
digit 1 |
MCC
digit 3 |
2 |
MSIN
digit 1 |
MNC
digit 2 |
3 |
MSIN
digit 3 |
MSIN
digit 2 |
4 |
MSIN
digit 5 |
MSIN
digit 4 |
5 |
MSIN
digit 7 |
MSIN
digit 6 |
6 |
MSIN
digit 9 |
MSIN
digit 8 |
7 |
NSAPI |
MSIN
digit 10 |
8 |
| TID
Format |
|
MCC, MNC, MSIN digits
Parts of the IMSI (defined
in GMS 04.08).
NSAPI
Network service access
point identifier.
Interested in more details about testing
this protocol?
LLC
GSM 04.64 version 6.1.0 http://www.etsi.fr
LLC defines the logical link control layer
protocol to be used for packet data transfer between the mobile
station (MS) and a serving GPRS support node (SGSN). LLC spans
from the MS to the SGSN and is intended for use with both acknowledged
and unacknowledged data transfer.
The frame formats defined for LLC are based
on those defined for LAPD and RLP. However, there are important
differences between LLC and other protocols, in particular with
regard to frame delimitation methods and transparency mechanisms.
These differences are necessary for independence from the radio
path.
LLC supports two modes of operation:
- Unacknowledged peer-to-peer operation.
- Acknowledged peer-to-peer operation.
All LLC layer peer-to-peer exchanges are
in frames of the following format:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octets |
Address Field |
1 |
| Control
Field
(variable length, max. 36 octets)
|
2-n |
| |
| |
Information
Field
(variable length, max. N201 octets) |
|
| |
| |
| |
| |
| |
Frame Chack Sequence Field |
|
(3 octets) |
|
| |
|
Address
The address field contains
the SAPI and identifies the DLCI for which a downlink frame
is intended and the DLCI transmitting an uplink frame. The length
of the address field is 1 byte and it has the following format:
8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
PD |
C/R |
XX |
SAPI |
|
PD
Protocol Discriminator bit indicates
whether a frame is an LLC frame or belongs to a different protocol.
LLC frames have the PD bit set to 0. If a frame with the PD
bit set to 1 is received, then it is treated as an invalid frame.
C/R Identifies
a frame as either a command or a response. The MS side sends
commands with the C/R bit set to 0, and responses with the C/R
bit set to 1. The SGSN side does the opposite; i.e., commands
are sent with C/R set to 1 and responses are sent with C/R set
to 0. The combinations for the SGSN side and MS side are as
follows.
| Type |
Direction |
C/R value |
| Command |
SGSN side to MS side |
1 |
| Command |
MS side to SGSN side |
0 |
| Response |
SGSN side to MS side |
0 |
| Response |
MS side to SGSN side |
1 |
XX
Reserved.
SAPI
Service Access Point Identifier
identifies a point at which LLC services are provided by an
LLE to a layer-3 entity.
Control
Identifies the type of
frame. Four types of control field formats are specified:
- Confirmed information transfer (I format)
- Supervisory functions (S format)
- Unconfirmed information transfer (UI format)
- Control functions (U format)
Information
Contains the various commands
and responses.
FCS
Frame check sequence field
consists of a 24 bit cyclic redundancy check (CRC) code. The
CRC-24 is used to detect bit errors in the frame header and
information fields.
Interested in more details about testing
this protocol?
NS
GSM 08.16 version 6.1.0 http://www.etsi.fr
The Network Service performs the transport
of NS SDUs between the SGSN (serving GPRS support node) and
BSS (base station system). Services provided to the NS user
include:
- Network Service SDU transfer. The Network
Service entity provides network service primitives allowing
for transmission and reception of upper layer protocol data
units between the BSS and SGSN. The NS SDUs are transferred
in order by the Network Service, but under exceptional circumstances
order may not be maintained.
- Network congestion indication. Congestion
recovery control actions may be performed by the Sub-Network
Service (e.g. Frame Relay). Congestion reporting mechanisms
available in the Sub-Network Service implementation shall
be used by the Network Service to report congestion.
- Status indication. Status indication shall
be used to inform the NS user of the NS affecting events e.g.
change in the available transmission capabilities.
NS PDUs are of the following format:
| 8 |
7 |
6 |
5 |
4 |
3 |
2 |
1 |
Octets |
PDU type |
1 |
Information Elements |
2-n |
|
|
PDU type
PDU type may be:
NS-ALIVE
NS-ALIVE-ACK
NS-BLOCK
NS-BLOCK-ACK
NS-RESET
NS-RESET-ACK
NS-STATUS
NS-UNBLOCK
NS-UNBLOCK-ACK
NS-UNITDATA
Information element value
The following IEs may
be present depending on the PDU type:
Cause
NS-VCI
NS PDU
BVCI
NSEI
Interested in more details about testing
this protocol?
RLP
GSM 04.22 version 7.0.1 http://www.etsi.fr
The Radio Link Protocol (RLP) for data
transmission over the GSM PLMN covers the Layer 2 functionality
of the ISO OSI reference model. It has been tailored to the
needs of digital radio transmission and provides the OSI data
link service. RLP spans from the Mobile Station (MS) to the
interworking function located at the nearest Mobile Switching
Center (MSC) or beyond. Three versions of RLP exist.
| Version 0: |
Single-link basic version |
| Version 1: |
Single-link extended version |
| Version 2: |
Multi-link version. |
The RLP frames have a fixed length
of either 240 or 576 bits consisting of a header, information
field and an FCS field.
The format of the 240-bit frame is:
| Header |
Information |
FCS |
| 16
bit |
200
bit |
24
bit |
| 24
bit |
192
bit |
24
bit |
| RLP
240-bit frame format |
The header is 16 bits in versions 0
and 1 and in version 2 (U frames). It is 24 bits in version
2 (S and I+S frames).
The format of the 576-bit frame is:
The header is 16 bits in version 1
and version 2 (U frames), and 24 bits in version 2 (S and I+S)
frames.
Header
Contains control information of one of the following
3 types: unnumbered protocol control information (U frames),
supervisory information (S frames) and user information carrying
supervisory information piggybacked (I+S frames).
FCS
This is the Frame Check Sequence field.
The RLP entity will be in the Asynchronous Balanced Mode (ABM),
which is the data link operation mode; or Asynchronous Disconnected
Mode (ADM), which is the data link non-operational mode.
Header structure of versions 0 and 1
N(S) is a bit 4 low order bit and N(R) is a bit 11 low
order bit.
| U |
C/R |
X |
X |
1 |
1 |
1 |
1 |
1 |
1 |
P/F |
M1 |
M2 |
M3 |
M4 |
M5 |
X |
| S |
C/R |
S1 |
S2 |
0 |
1 |
1 |
1 |
1 |
1 |
|
N(R) |
| I+S |
C/R |
S1 |
S2 |
N(S)
|
P/F |
N(R) |
| Bits
1-16 |
Header structure
of version 2
S is a L2R status Bit, N(S) is a bit 1 low order bit,
N(R) is a bit 14 low order bit and UP is a UP bit.
| U |
C/R |
X |
X |
1 |
1 |
1 |
1 |
1 |
1 |
P/F |
M1 |
M2 |
M3 |
M4 |
M5 |
X |
|
|
|
| S |
X |
X |
X |
0 |
1 |
1 |
1 |
1 |
1 |
P/F |
S1 |
S2 |
N(R) |
X |
UP |
| I+S |
N(S)
|
P/F |
S1 |
S2 |
N(R) |
S |
UP |
| Bits
1-24 |
C/R
The Command Response Bit indicates whether the frame
is a command or a response frame. It can have the following
values:
P/F
The Poll/Final bit marks a special instance of command/response
exchange
X
Don't care
Unnumbered Frames (U)
The M1 M2 M3 M4 and M5 bits have the following values
in the U frames according to the type of information carried:
SABM
UA
DISC
DM
NULL
UI
XID
TEST
REMAP |
11100
0011
00010
11000
11110
00000
11101
00111
10001 |
SABM11100
The Set Asynchronous balance mode is used either to initiate
a link for numbered information transfer or to reset a link
already established.
UA00110
The Unnumbered Acknowledge is used as a response to acknowledge
an SABMM or DISC command.
DISC00010
The disconnect is used to disestablish a link previously
established for information transfer.
DM11000
The disconnected mode encoding is used as a response
message.
NULL11110
UI 00000
Unnumbered information signifies that the information
field is to be interpreted as unnumbered information.
XID11101
Exchange Identification signifies that the information
field is to be interpreted as exchange identification, and is
used to negotiate and renegotiate parameters of RLP and layer
2 relay functions.
TEST 00111
The information field of this frame is test information.
REMAP 0001
A remap exchange takes place in ABM following a change
of channel coding. If an answer is not received within a specific
time, then the mobile end enters ADM.
S and I+S frames
N(S)
The send sequence number contains the number of the I
frame.
N(R)
The Receive sequence number is used in ABM to designate
the next information frame to be sent and to confirm that all
frames up to and including this bit and been received correctly.
S
S represents the L2 status bit.
The S1, S2 bits can have the following
significance in the S and I+S frames:
| RR |
00 |
| REJ |
01 |
| RNR |
10 |
| SREJ |
11 |
RR
Receive Ready can be used either as a command or a response.
It clears any previous busy condition in that area.
REJ
The Reject encoding is used to indicate that in numbered
information transfer 1 or more out-of-sequence frames have been
received.
RNR
The Receive Not Ready indicates that the entity is not
ready to receive numbered information frames.
SREJ
Selective Reject is used to request retransmission of
a single frame.
UP
This is used in version 2 to indicate that a service
level upgrading will increase the throughput.
Interested in more details about testing
this protocol?
SMSCB
ETSI TS 124 012. (You can download
all the ETSI files from www.ETSI.org)
The Short Message Service Cell Broadcast
(SMSCB) protocol is a service in which short messages may be
broadcast from a PLMN to Mobile Stations (MS)s. SMSCB messages
come from different sources (e.g. traffic reports, weather reports).
The source and subject of the SMSCB message is identified by
| 
