Decks
Entity Decks
will be developed as a container which contains combined data of all defined singular decks.
As a child of entity Decks
you have already included the multiple (select one of more) entity Deck
(see Developing a ship design process).
The entity Decks
can contain one or more Deck
entities, each containing the same parameters and relations. However, the user can provide different input values for every Deck
.
During the computation, the user will be asked the number of Deck
entities he/she wants to include. If you include the Nr
parameter in the "container” entity Decks
, this will be the parameter which determines the number of Deck
entities that will be placed, because Nr
contains an @NRINST attribute in the Data, as explained in Some handy attributes.
Parameter name | Dimension | Determined by | Reference | In Class |
| [m^2] | USR: User or system/equation | Total deck area |
|
| [Telitab] | USL: User or system/function | Table of deck data | Dimensions |
| [m^2] | USR: User or system/equation | Total accommodation deck area | Dimensions |
| [Telitab] | USL: User or system/function | Table of all accommodation deck data | Dimensions |
Decks
: Nr
, Total_deck_area
, Deck_data#
, Total_accommodation_area
, Total_accommodation_area#
, QEntityRef
.Tip
If you forgot in which class you put a parameter, use the seach box at the top of the Knowledge Browser to find it for you.
Relations for these parameters will be included at a later stage, because these will be clearer to you when you first have developed the entity Deck
.
Deck
Mass calculation
under Top goals/Undefined
. This class will be used later on.
Parameter name | Dimension | Determined by | Reference | In Class |
| [m] | VR: User only | Width | Dimensions |
| [m^2] | USR: User or system/equation | Area | Dimensions |
| [Str] | VR: User only | Define function of deck | General |
| [m] | VR: User only | Length | Dimensions |
| [t/m^2] | USR: User or system/equation | Weight factor per area | Mass calculation |
| [m] | VR: User only | Aft deck position in X (longitudinal) direction | Dimensions |
| [m] | VR: User only | Front deck position in X (longitudinal) direction | Dimensions |
| [ID] | VR: User only | Define aft (longitudinal) position of deck by selecting a transverse reference plane | Dimensions |
| [ID] | VR: User only | Define front (longitudinal) position of deck by selecting a transverse reference plane | Dimensions |
| [ID] | VR: User only | Define Z (vertical) position of deck by selecting a horizontal reference plane | Dimensions |
Deck
: Name$
, Area
, B
, Deck_function$
, L
, Weight_area_factor
, X_aft
, X_aft_plane_ID
, X_front
, X_front_plane_ID
, Z
, and Z_plane_ID
.B = ENTITY#(12).Boa
(12 is the value of QEntityId
of entity MainDimensions)
Area = L*B
L = X_front - X_aft
QEntityData
All parameters in entity Deck
should be in list view and not in table view, because all values are single values. So, parameters Z
and Name$
in entity Deck
are automatically placed in the table view because you have set a @MULTVAL attribute on these parameters earlier.
Deck
and remove the @MULTVAL attribute locally.A second option would be to set @NOMULTVAL on parameter QEntityData
of entity Deck
. Now all @MULTVAL attributes within this entity will be ignored.
The user (ship designer) has to indicate the starting position and end position of a deck in longitudinal direction of the ship, with the parameters X_aft
and X_front
. This determines the length L
of the ship.
Furthermore, it is assumed that the width B
of a deck is equal to the width over all Boa
of entity MainDimensions.
To assume rectangular decks the area is calculated by L*B
.
You might wonder why there is a Weight_factor_area
parameter. This is explained later on, but the main reason is that this parameter is a property of the Deck
and as such should be part of the Deck
entity. However, hereafter you will discover that the input for this value should not be given in this entity, but as part of the Mass calculation
entity. In order not to show the parameter in this entity:
Weight_factor_area
We will come back to this last parameter in Mass calculation.
How to connect the start and end position to the reference planes will be discussed next.
Now, you will create a selection list from available data to position a deck with respect to specified reference planes.
The way to do this will be explained by determining the aft position of a deck.
X_aft_plane_ID:
:14
(QEntityID of Transverse planes)
.The entity Transverse planes
is used to create a selection list from with the other attributes.CaseID
. The parameter CaseID
is the parameter (of entity Transverse planes
) whose values must be listed for selection.Name$
. The parameter Name$
defines the case description that must be displayed in the selection list.Note that you may have a different value than 14 here, because it depends on the sequence of creating entities in the tree!
By including the attributes as described above, the user can select a reference plane from a drop down list, containing the names of all defined transverse reference planes. The result of the selection is a value of parameter CaseID
, but the value of parameter Name$
is shown to the user instead.
The value of parameter X_aft
should be the value of X
from the selected transverse plane.
X_aft = ENTITY#(14).X.X_aft_plane_ID
This means the following: entity Transverse planes
(in this example 14) contains a table of transverse planes, in which each column (case) represents a transverse plane. When the user has selected the second name from the table, the value of X_aft_ID
will be 2 (although Name$
was presented to the user). So, the value of X_aft
will become the second “X” value from the table within entity Transverse planes
(X_aft = ENTITY#(14).X.2
)
X_front_plane_ID
as you did for X_aft_plane_ID
.X_front = ENTITY#(14).X.X_front_plane_ID
Z_plane_ID.
Here, you have to refer to the QEntityID
of entity Horizontal planes
, in our example 15.Z = ENTITY#(15).Z.Z_plane_ID
As shown in the calculation result above, each Deck
entity node name contains the name and height of a deck. This can be accomplished by using the attribute @OBJECTTITLE in parameter QEntityData of entity Deck. You can provide a flexible string, for example:
@OBJECTTITLE:"Deck_" + Name$ + "; deck height = " + STR$(Z) + " m"
Here, everything between quotes will be presented as text. The value of a string parameter like Name$
will also be shown as text. And, if you also want to present the value of a parameter which is not of the string type, you first have to convert it to a string, for example STR$(Z)
.
QEntityData
. For this, double click on the parameter value. The content will open in a larger editor window.You now will create a table with a subset of parameter values of all defined decks.
The QEntity()
expression collects parameters of all child entities.
Decks
:Deck_data# = QEntity(@Name$, @Deck_function$, @Z, @X_aft, @X_front, @Area)
The total accommodation area will be shown separately. For this, parameter “Total_accommodation_area#
, which is a Telitab (as its name ends with #). It should only contain data of decks for which Deck_function$
returns Accommodation
. Use the QUERY# function, which returns a Telitab subset on the basis of a set of search criteria.
Decks
:Total_accommodation_area# = QUERY#(Deck_data#, "NullString", "Accommodation":"Deck_function$")
Next sums of the datasets will be made using the SUM function.
Total_deck_area = SUM(Deck_data#, 1, "Area")
Total_accommodation_area = INCASE(Total_accommodation_area# = "0" + Qcrlf, THEN, 0, ELSE, SUM(Total_accommodation_area#, 1, "Area"))
The second relation has a condition (the INCASE()
function). If Total_accommodation_area#
is an empty table (which is possible if the user does not create decks with "Deck_function$" = "Accommodation"
) then the total accommodation deck area is 0 [m2]. Because the content of an empty table in Quaestor will be: "0" + Qcrlf (in which Qcrlf is a Carriage return-line feed string constant) this should be the value to test the parameter against.
QEntityRef
parameter to Decks
Combined data of all decks
” to QEntityRef
QEntityData
Bulkheads
As mentioned in Developing a ship design process, this ship configurator uses a different entity structure for defining (transverse) bulkheads in comparison with defining decks. Of course the same entity structure could be used, but it is more instructive to present (and develop) a different approach.
The development of the Bulkheads
entity is comparable to the Decks
entity. However, in the previous paragraphs a multiple entity was used to enable the user to define one or more decks. Here an entity is developed where the user can create one table to define one or more transverse bulkheads instead of several Deck
entities. Contrary to Deck
(child of Decks)
, which is multiple, the child entity Bulkheads
(child of Bulkheads)
is singular.
Parameter name | Dimension | Determined by | Reference | In Class |
| [m] | USR: User or system/equation | Height | Dimensions |
| [ID] | VR: User only | Define X position of bulkhead by selecting a transverse reference plane | Dimensions |
| [m] | VR: User only | Bottom position bulkhead in Z (vertical) direction | Dimensions |
| [m] | VR: User only | Top position bulkhead in Z (vertical) direction | Dimensions |
| [ID] | VR: User only | Define bottom Z (vertical) position of bulkhead by selecting a horizontal reference plane | Dimensions |
| [ID] | VR: User only | Define top Z (vertical) position of bulkhead by selecting a horizontal reference plane | Dimensions |
Bulkheads: Nr
, Name$
, Area
, B
, H
, Weight_area_factor
, X
, X_plane_ID
, Z_bottom
, Z_bottom_plane_ID
, Z_top
, and Z_top_plane_ID
.With exception of parameter Nr
and the QEntity
* parameters all parameters must be placed within the table view.
QEntityData
Again, a selection list must be created from data in the reference entities to, in this case, position a bulkhead. In section 3 it was explained how to achieve this for decks.
X_plane_ID
, Z_bottom_plane_ID
, and Z_top_plane_ID
.Area = B*H
B = ENTITY#(12).Boa
(12 is the value of QEntityId
of entity MainDimensions)
H = Z_top - Z_bottom
X = ENTITY#(14).X.X_plane_ID
(14 is the value of QEntityId
of entity Transverse planes
)
Z_bottom = ENTITY#(15).Z.Z_bottom_plane_ID
(15 is the value of QEntityId
of entity Horizontal planes
)
Z_top = ENTITY#(15).Z.Z_top_plane_ID
(15 is the value of QEntityId
of entity Horizontal planes
)