# ASN.1 module ETSI-ITS-DSRC-AddGrpC
OID: _{ itu-t (0) identified-organization (4) etsi (0) itsDomain (5) wg1 (1) ts103301 (103301) dsrc (6) addgrpc (0) version2 (2) }_
## Imports:
* **[ETSI-ITS-DSRC](ETSI-ITS-DSRC.md)** *{ itu-t (0) identified-organization (4) etsi (0) itsDomain (5) wg1 (1) ts103301 (103301) dsrc (6) version2 (2) }*
* **[ETSI-ITS-CDD](ETSI-ITS-CDD.md)** *{ itu-t (0) identified-organization (4) etsi (0) itsDomain (5) wg1 (1) 102894 cdd (2) major-version-4 (4) minor-version-1 (1) } WITH SUCCESSORS*
## Data Elements:
### ConnectionManeuverAssist-addGrpC
This Element adds positioning support from the infrastructure to the vehicle.
* _itsStationPosition_ of type [**ItsStationPositionList**](#ItsStationPositionList) OPTIONAL
* itsStationPositions
defines a list of ITS stations (e.g. vehicles) and their corresponding position on
the driving lane as defined in the lane topology of the MapData message or the GNSS position
deviation of the ITS Station from the high precision reference position in X/Y coordinates. It
enables accurate, real-time positioning support to the moving ITS entities by the infrastructure.*
**Categories:** @revision: V1.3.1
```asn1
ConnectionManeuverAssist-addGrpC ::= SEQUENCE {
itsStationPosition ItsStationPositionList OPTIONAL,
...
}
```
### ConnectionTrajectory-addGrpC
The data frame âConnectionTrajectory-addGrpCâ defines the trajectory for travelling through the
conflict area of an intersection and connects e.g an ingress with an egress lane. The trajectory is defined
by two or more nodes. The starting node overlaps e.g. with the node of the ingress lane towards the
conflict zone. The ending node overlaps e.g. with the first node of the connected egress lane. See the
example in clause G.8.2.5.
ânodesâ defines a list of nodes for the trajectory. It defines e.g. a geometric trajectory from an ingressing
to a connected egressing lane and the X/Y position value of the first node of the trajectory is the same as
the node of the ingress lane. The X/Y position of the last node is the same as the X/Y position of the first
node of the egressing lane.
âconnectionIDâ defines the identifier of an allowed âmaneuverâ (e.g. ingress / egress relation). A generic
Lane offers one or more allowed âmaneuversâ, therefore the trajectory is reference to the related
âmaneuverâ.
Note: "Reg-GenericLane" allows providing up to 4 connecting trajectories. In case a lane has more than
4 connecting trajectories, priority should be given to connecting trajectories of motorized traffic and
complex manoeuvres.
* _nodes_ of type [**NodeSetXY**](ETSI-ITS-DSRC.md#NodeSetXY)
* _connectionID_ of type [**LaneConnectionID**](ETSI-ITS-DSRC.md#LaneConnectionID)
* regional
/ ConnectionTrajectory:
The data frame âConnectionTrajectory-addGrpCâ defines the trajectory for travelling e.g. through the
conflict area of an intersection. The trajectory is defined by two or more nodes. In the example in Figure
G.1, the first node position of the trajectory (T2-1) is matching to the node of the ingress lane towards
the conflict zone (L2-1), and the ending node (T2-6) and the first node of the connected egress share the
same position (L6-1). Additionally, the data frame âNodeLinkâ (G.5.2.3) is used to define a clear relation
between the trajectory endpoint and the connected lane point.
T610-7 (last node)
node.id = 7
**Categories:** @revision: V1.3.1
```asn1
ConnectionTrajectory-addGrpC ::= SEQUENCE {
nodes NodeSetXY,
connectionID LaneConnectionID,
...
}
```
### IntersectionState-addGrpC
The data frame âIntersectionState-addGrpCâ defines a list of prioritization responses e.g. public
transport acceleration.
The signal prioritization (e.g. public transport) procedure in this profile follows two strategies.
â For simple prioritization requests, the CAM/SPAT messages are used. This allows the migration
of old legal systems towards C-ITS. In this case, the CAM message is used to trigger the request
towards the traffic light controller. The traffic light controller checks the request and
broadcasts the status for the priority request within the âIntersectionState-addGrpCâ data
element (see G.5.1.9).
â For more complex signal requests, the SignalRequestMessage/SignalStatusMessage messages are
be used.
regional / IntersectionState:
This data element includes additional data content âIntersectionState-addGrpCâ defined in this profile
(see G.5.1.3,). The content is included using the regional extension framework as defined in G.7.4.
NOTE
â
â
The signal prioritization (e.g. public transport) procedure in this profile follows two strategies.
For simple prioritization requests, the CAM/SPAT messages are used. This allows the migration of old legal
systems towards C-ITS. In this case, the CAM message is used to trigger the request towards the traffic light
controller. The traffic light controller checks the request and broadcasts the status for the priority request
within the âIntersectionState-addGrpCâ data element (see G.5.1.3).
For more complex signal requests, the SignalRequestMessage/SignalStatusMessage messages will be used.
The âpriorityâ data element of the âDF_IntersectionStateâ is not used in this profile.
* _activePrioritizations_ of type [**PrioritizationResponseList**](#PrioritizationResponseList) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
IntersectionState-addGrpC ::= SEQUENCE {
activePrioritizations PrioritizationResponseList OPTIONAL,
...
}
```
### LaneAttributes-addGrpC
Lanes may have limitations regarding vehicle height (e.g. due to a tunnel) and vehicle weight (e.g. due to
a bridge). To indicate these limitations, two data elements are added which are already defined in J2735
for other messages.
* _maxVehicleHeight_ of type [**VehicleHeight**](ETSI-ITS-DSRC.md#VehicleHeight) OPTIONAL
* _maxVehicleWeight_ of type [**VehicleMass**](ETSI-ITS-CDD.md#VehicleMass) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
LaneAttributes-addGrpC ::= SEQUENCE {
maxVehicleHeight VehicleHeight OPTIONAL,
maxVehicleWeight VehicleMass OPTIONAL,
...
}
```
### MapData-addGrpC
The data frame âMapData-addGrpCâ defines a list of three-dimensional positions of signal heads in an
intersection. It enables vehicles to identify the signal head location for optical evaluation of the traffic
light. Combined with the SPAT/MapData messages, it enables e.g. driving vehicles to enhance safety
decision in critical situations.
* _signalHeadLocations_ of type [**SignalHeadLocationList**](#SignalHeadLocationList) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
MapData-addGrpC ::= SEQUENCE {
signalHeadLocations SignalHeadLocationList OPTIONAL,
...
}
```
### MovementEvent-addGrpC
Priority and preemption have a considerable impact to the timing parameters in the SPAT message
(eventState). User acceptance is expected to increase if the reason for sudden changes in timing
parameters is communicated to them.
* _stateChangeReason_ of type [**ExceptionalCondition**](#ExceptionalCondition) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
MovementEvent-addGrpC ::= SEQUENCE {
stateChangeReason ExceptionalCondition OPTIONAL,
...
}
```
### NodeAttributeSet-addGrpC
The data frame "NodeAttributeSet-addGrpC" defines additional attributes to support public transport
and to enable a simple way of defining lane links.
myCommittee | 13.06.2019 | 19017046,Siemens Mobility GesmbH,Dipl.-Ing. Thomas Ritter
âptvRequestâ defines control types attached to a node on a lane used by public transport for triggering
the transmission of messages (e.g. prioritization request). It includes control points for public transport
prioritization. These control points are currently implemented by legacy systems using hardware
sensors mounted on the roadside.
ânodeLinkâ defines a link to one or to a set of another node/lane from this node. The nodeLink allows to
set a link between specific nodes of generic lanes or trajectories. This supports e.g. lane
merging/diverging situations (G.8.2.7) and the linking of trajectories in the conflict zone to lanes (see
example G.8.2.5).
ânodeâ defines an identifier of this node.
* _ptvRequest_ of type [**PtvRequestType**](#PtvRequestType) OPTIONAL
* _nodeLink_ of type [**NodeLink**](#NodeLink) OPTIONAL
* _node_ of type [**Node**](#Node) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
NodeAttributeSet-addGrpC ::= SEQUENCE {
ptvRequest PtvRequestType OPTIONAL,
nodeLink NodeLink OPTIONAL,
node Node OPTIONAL,
...
}
```
### Position3D-addGrpC
The data frame âPosition3D-addGrpCâ includes the altitude data element defined in the common data dictionary [G1].
regional / Position3D:
The âelevationâ data element is replaced by the ETSI âaltitudeâ data element using the regional
extension. The âaltitudeâ data element is defined in âPosition3D-addGrpCâ of this profile (see G.5.1.8).
âPosition3D-addGrpCâ extends the âDF_Position3Dâ using the regional extension framework as defined
in G.7.7.
* _altitude_ of type [**Altitude**](ETSI-ITS-CDD.md#Altitude)
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
Position3D-addGrpC ::= SEQUENCE {
altitude Altitude,
...
}
```
### RestrictionUserType-addGrpC
The data frame âRestrictionUserType-addGrpCâ defines the driving restriction based on toxic emission
type. . The meaning of the word 'restriction' is ambiguous as it may have a double interpretation, being:
only these vehicles are allowed OR these vehicles are not allowed and all others are. The former is what
is intended by the base standard.
regional / RestrictionUserType:
This data element includes additional data content âRestrictionUserType-addGrpCâ defined in this
profile (see G.5.1.9). The content is included using the regional extension framework as defined in G.7.8.
G.8.3 Data elements
* _emission_ of type [**EmissionType**](#EmissionType) OPTIONAL
* _fuel_ of type [**FuelType**](ETSI-ITS-DSRC.md#FuelType) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
RestrictionUserType-addGrpC ::= SEQUENCE {
emission EmissionType OPTIONAL,
fuel FuelType OPTIONAL,
...
}
```
### RequestorDescription-addGrpC
Some road authorities like to give priority to vehicles based on the type of fuel they use. In addition,
electric vehicles may receive priority based on their battery status.
* _fuel_ of type [**FuelType**](ETSI-ITS-DSRC.md#FuelType) OPTIONAL
* _batteryStatus_ of type [**BatteryStatus**](#BatteryStatus) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
RequestorDescription-addGrpC ::= SEQUENCE {
fuel FuelType OPTIONAL,
batteryStatus BatteryStatus OPTIONAL,
...
}
```
### SignalStatusPackage-addGrpC
The traffic control centre (TCC) may advice a public transport vehicle (e.g. bus) to synchronize his
travel time. This may happen when, for example, two busses, due to special traffic conditions, are out of
schedule; the first might be too late, the second too fast. The consequence is that the second is driving
just behind the first and is empty as all passengers are within the first one. To avoid this often-occurring
situation, the TCC transmits time synchronization advices to the public transport vehicles using the
signal status message. The "PrioritizationResponseStatus" provides optionally the reason for
prioritization response rejection.
ASN.1 representation:
* _synchToSchedule_ of type [**DeltaTime**](ETSI-ITS-DSRC.md#DeltaTime) OPTIONAL
* _rejectedReason_ of type [**RejectedReason**](#RejectedReason) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
SignalStatusPackage-addGrpC ::= SEQUENCE {
synchToSchedule DeltaTime OPTIONAL,
rejectedReason RejectedReason OPTIONAL,
...
}
```
### ItsStationPosition
The data frame âItsStationPositionâ is used to provide real-time positioning information feedback to a
specific ITS station (e.g. vehicle, pedestrian, bicycle) by infrastructure equipment. The position
information includes, for example, the driving, crossing lane and/or the X/Y coordinates in relation to
the reference position of the MapData. The "timeReference" indicates the time stamp of the the
message (received from an ITS station) for which the positioning feedback has been computed.
NOTE
The computation of the positioning feedback is out of focus of this standard.
* _stationID_ of type [**StationID**](ETSI-ITS-CDD.md#StationID)
* _laneID_ of type [**LaneID**](ETSI-ITS-DSRC.md#LaneID) OPTIONAL
* _nodeXY_ of type [**NodeOffsetPointXY**](ETSI-ITS-DSRC.md#NodeOffsetPointXY) OPTIONAL
* _timeReference_ of type [**TimeReference**](#TimeReference) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
ItsStationPosition ::= SEQUENCE {
stationID StationID,
laneID LaneID OPTIONAL,
nodeXY NodeOffsetPointXY OPTIONAL,
timeReference TimeReference OPTIONAL,
...
}
```
### ItsStationPositionList
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
ItsStationPositionList ::= SEQUENCE SIZE(1..5) OF ItsStationPosition
```
### Node
The data frame âNodeâ is used to to identify a node of a lane (waypoint) by its âlaneâ and node identifier
âidâ. The âintersectionIDâ is used if the referenced lane belongs to an adjacent intersection. If the node
belongs to a connection trajectory (G.5.1.2) the âconnectionIDâ is used.
* _id_ of type **INTEGER**
* _lane_ of type [**LaneID**](ETSI-ITS-DSRC.md#LaneID) OPTIONAL
* _connectionID_ of type [**LaneConnectionID**](ETSI-ITS-DSRC.md#LaneConnectionID) OPTIONAL
* _intersectionID_ of type [**IntersectionID**](ETSI-ITS-DSRC.md#IntersectionID) OPTIONAL
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
Node ::= SEQUENCE {
id INTEGER,
lane LaneID OPTIONAL,
connectionID LaneConnectionID OPTIONAL,
intersectionID IntersectionID OPTIONAL,
...
}
```
### NodeLink
The data frame âNodeLinkâ is used to to define a link list (one or more) of nodes (G.5.2.2.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
NodeLink ::= SEQUENCE SIZE (1..5) OF Node
```
### PrioritizationResponse
The data frame âPrioritizationResponseâ is used to provide the prioritization status response and the
signal group identifier for a specific ITS station (e.g. vehicle).
* _stationID_ of type [**StationID**](ETSI-ITS-CDD.md#StationID)
* _priorState_ of type [**PrioritizationResponseStatus**](ETSI-ITS-DSRC.md#PrioritizationResponseStatus)
* _signalGroup_ of type [**SignalGroupID**](ETSI-ITS-DSRC.md#SignalGroupID)
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
PrioritizationResponse ::= SEQUENCE {
stationID StationID,
priorState PrioritizationResponseStatus,
signalGroup SignalGroupID,
...
}
```
### PrioritizationResponseList
The data frame âPrioritizationResponseListâ defines a list of prioritization response entries.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
PrioritizationResponseList ::= SEQUENCE SIZE(1..10) OF PrioritizationResponse
```
### SignalHeadLocation
The data frame âSignalHeadLocationâ defines the XYZ position of a signal head within an intersection
and indicates the related signal group identifier.
* _nodeXY_ of type [**NodeOffsetPointXY**](ETSI-ITS-DSRC.md#NodeOffsetPointXY)
* _nodeZ_ of type [**DeltaAltitude**](ETSI-ITS-CDD.md#DeltaAltitude)
* _signalGroupID_ of type [**SignalGroupID**](ETSI-ITS-DSRC.md#SignalGroupID)
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
SignalHeadLocation ::= SEQUENCE {
nodeXY NodeOffsetPointXY,
nodeZ DeltaAltitude,
signalGroupID SignalGroupID,
...
}
```
### SignalHeadLocationList
The data frame âSignalHeadLocationListâ defines a list of traffic light signal head locations (Error!
Reference source not found.) in relation to the intersection reference position.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
SignalHeadLocationList ::= SEQUENCE (SIZE(1..64)) OF SignalHeadLocation
```
### BatteryStatus
The data element âBatteryStatusâ element defines an enumerated list of battery states.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
BatteryStatus ::= ENUMERATED {
unknown,
critical,
low,
good,
...
}
```
### EmissionType
The data element âEmissionTypeâ element defines an enumerated list of toxic emission types for
vehicles.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
EmissionType ::= ENUMERATED {
euro1,
euro2,
euro3,
euro4,
euro5,
euro6,
...
}
```
### ExceptionalCondition
The data element âExceptionalConditionâ element defines a list of reasons for sudden changes in
eventState parameters, thereby offering a reason for extended waiting times.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
ExceptionalCondition ::= ENUMERATED {
unknown,
publicTransportPriority,
emergencyVehiclePriority,
trainPriority,
bridgeOpen,
vehicleHeight,
weather,
trafficJam,
tunnelClosure,
meteringActive,
truckPriority,
bicyclePlatoonPriority,
vehiclePlatoonPriority,
...
}
```
### PtvRequestType
The data element âPtvRequestTypeâ element defines a list of activation requests used for C-ITS
migration of legacy public transport prioritization systems. The activation points are used while
approaching to an intersection.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
PtvRequestType ::= ENUMERATED {
preRequest,
mainRequest,
doorCloseRequest,
cancelRequest,
emergencyRequest,
...
}
```
### RejectedReason
The data element âRejectedReasonâ element defines a list of reasons for rejected priority requests.
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
RejectedReason ::= ENUMERATED {
unknown,
exceptionalCondition,
maxWaitingTimeExceeded,
ptPriorityDisabled,
higherPTPriorityGranted,
vehicleTrackingUnknown,
...
}
```
### TimeReference
The data element âTimeReferenceâ element defines a value in milliseconds in the current minute
related to UTC time. A range of 60 000 covers one minute (60 seconds * 1 000 milliseconds)
* xxxxx
.
**Categories:** @revision: V1.3.1
```asn1
TimeReference ::= INTEGER { oneMilliSec(1) } (0..60000)
```