This is usually the approach for dives without a dive computer. The basic record of information within Subsurface is a dive. The most important information in a simple dive logbook usually includes dive type, date, time, duration, depth, the names of your dive buddy and of the dive master or dive guide, and some remarks about the dive. Subsurface can store much more information than this for each dive. In order to add a dive to a dive log, select Log → Add Dive from the Main Menu. The program then shows three panels to enter information for a dive: two tabs in the Info panel (Notes and Equipment), as well as the Dive Profile panel that displays a graphical profile of each dive. These panels are respectively marked A, B and C in the figure below. Each of these tabs will now be explained for data entry.

When one edits a field in Notes or Equipment panels, Subsurface enters Editing Mode, indicated by the message in the blue box at the top of the Notes panel (see the image below). This message is displayed in all the panels under Notes and Equipment when in Editing Mode.

The Save button should only be selected after all the parts of a dive have been entered. When entering dives by hand, the Info, Equipment and Profile tabs should be completed before saving the information. By selecting the Save button, a local copy of the information for this specific dive is saved in memory. When one closes Subsurface, the program will ask again, this time whether the complete dive log should be saved on disk or not.

If a user has been diving for some time, it is possible that several dives were logged using other dive log software. This information does not need retyping because these dive logs can probably be imported into Subsurface. Subsurface will import dive logs from a range of other dive log software. While some software is supported natively, for others the user has to export the logbook(s) to an intermediate format so that they can then be imported by Subsurface. Currently, Subsurface supports importing CSV log files from several sources. APD LogViewer, XP5, Sensus and Seabear files are preconfigured, but because the import is flexible, users can configure their own imports. Manually kept log files (e.g. in spreadsheet) can also be imported by configuring the CSV import. Subsurface can also import UDDF and UDCF files used by some divelog software and some dive computers, like the Heinrichs & Weikamp DR5. Finally, for some divelog software like Mares Dive Organiser it is currently suggested to import the logbooks first into a webservice like divelogs.de and then import them from there with Subsurface, as divelogs.de supports a few additional logbook formats that Subsurface currently cannot parse.

If the format of other software is supported natively on Subsurface, it should be sufficient to select either Import → Import log files or File → Open log file. Subsurface supports the data formats of many dive computers, including Suunto and Shearwater. When importing dives, Subsurface tries to detect multiple records for the same dive and merges the information as best as it can. If there are no time zone issues (or other reasons that would cause the beginning time of the dives to be significantly different) Subsurface will not create duplicate entries.

Using the Subsurface Companion App on an Android device with a GPS or iPhone, the coordinates for the diving location can be automatically passed to the Subsurface dive log. The Companion App stores the dive locations on a dedicated Internet-based file server. Subsurface, in turn, can collect the localities from the file server.

To do this:

Many (if not most) divers take a camera with them and take photographs during a dive. One would like to associate each photograph with a specific dive. Subsurface allows one to load photos into a dive. Photos are superimposed on the dive profile, from where they can be viewed.

The Info tab gives some summary information about a particular dive that has been selected in the Dive List. Useful information here includes the surface interval before the dive, the maximum and mean depths of the dive, the gas volume consumed, the surface air consumption (SAC) and the number of oxygen toxicity units (OTU) incurred.

When using a dive computer, it often reports several data items that cannot easily be presented in a standardised way because the nature of the information differs from one dive computer to another. These data often comprise setup information, metadata about a dive, battery levels, no fly times, or gradient factors used during the dive. When possible, this information is presented in the Extra Data tab. Below is an image showing extra data for a dive using a Poseidon rebreather.

The Stats tab gives summary statistics for more than one dive, assuming that more than one dive has been selected in the Dive List using the standard Ctrl-click or Shift-click of the mouse. If only one dive has been selected, figures pertaining to only that dive are given. This tab shows the number of dives selected, the total amount of dive time in these dives, as well as the minimum, maximum and mean for the dive duration, water temperature and surface air consumption (SAC). It also shows the depth of the shallowest and deepest dives of those selected.

Of all the panels in Subsurface, the Dive Profile contains the most detailed information about each dive. The Dive Profile has a button bar on the left hand side that allows control over several display options. The functions of these buttons are described below. The main item in the Dive Profile is the graph of dive depth as a function of time. In addition to the obvious information of the depth it also shows the ascent and descent rates compared to the recommended speed of going up or down in the water column. This information is given using different colours:

The profile also includes depth readings for the peaks and troughs in the graph. Thus, users should see the depth of the deepest point and other peaks. Mean depth is plotted as a grey line, indicating mean dive depth up to a particular moment during the dive.

Water temperature is displayed with its own blue line with temperature values placed adjacent to significant changes.

The dive profile can include graphs of the partial pressures of O2, N2, and He during the dive (see figure above) as well as a calculated and dive computer reported deco ceilings (only visible for deep, long, or repetitive dives). Partial pressures of oxygen are indicated in green, those of nitrogen in black, and those of helium in dark red. These partial pressure graphs are shown below the profile data.

The air consumption graph displays the tank pressure and its change during the dive. The air consumption takes depth into account so that even when manually entering the start and end pressures the graph is not a straight line. Similarly to the depth graph the slope of the tank pressure gives the user information about the momentary SAC rate (Surface Air Consumption) when using an air integrated dive computer. Here the colour coding is not relative to some absolute values but relative to the average normalised air consumption during the dive. So areas that are red or orange indicate times of increased normalized air consumption while dark green reflects times when the diver was using less gas than average.

It is possible to zoom into the profile graph. This is done either by using the scroll wheel / scroll gesture of your mouse or trackpad. By default Subsurface always shows a profile area large enough for at least 30 minutes and 30m (100ft) – this way short or shallow dives are intuitively recognizable; something that free divers clearly won’t care about.

The profile can also include the dive computer reported ceiling (more precisely, the deepest deco stop that the dive computer calculated for each particular moment in time) as a red overlay on the dive profile. Ascent ceilings arise when a direct ascent to the surface increases the risk of a diver suffering from decompression sickness (DCS) and it is necessary to either ascend slower or to perform decompression stop(s) before ascending to the surface. Not all dive computers record this information and make it available for download; for example all of the Suunto dive computers fail to make this very useful data available to divelog software. Subsurface also calculates ceilings independently, shown as a green overlay on the dive profile. Because of the differences in algorithms used and amount of data available (and other factors taken into consideration at the time of the calculation) it is unlikely that ceilings from dive computers and from Subsurface are the same, even if the same algorithm and gradient factors (see below) are used. It is also quite common that Subsurface calculates a ceiling for non-decompression dives when the dive computer stayed in non-deco mode during the whole dive (represented by the dark green section in the profile at the beginning of this section). This is caused by the fact that Subsurface’s calculations describe the deco obligation at each moment during a dive, while dive computers usually take the upcoming ascent into account. During the ascent some excess nitrogen (and possibly helium) are already breathed off so even though the diver technically encountered a ceiling at depth, the dive still does not require an explicit deco stop. This feature allows dive computers to offer longer non-stop bottom times.

Gradient Factor settings strongly affect the calculated ceilings and their depths. For more information about Gradient factors, see the section on Gradient Factor Preference settings. The currently used gradient factors (e.g. GF 35/75) are shown above the depth profile if the appropriate toolbar buttons are activated. N.B.: The indicated gradient factors are NOT the gradient factors in use by the dive computer, but those used by Subsurface to calculate deco obligations during the dive. For more information external to this manual see:

The context menu for the Dive Profile is accessed by right-clicking while the mouse cursor is over the Dive Profile panel. The menu allows the creation of Bookmarks or Gas Change Event markers or manual CCR set-point changes other than the ones that might have been imported from a Dive Computer. Markers are placed against the depth profile line and with the time of the event set by where the mouse cursor was when the right mouse button was initially clicked to bring up the menu. Gas Change events involve a selection of which gas is being switched to, the list of choices being based on the available gases defined in the Equipment Tab. Set-point change events open a dialog allowing to choose the next set-point value. As in the planner, a set-point value of zero indicates the diver is breathing from an open circuit system while any non-zero value indicates the use of a closed circuit rebreather (CCR). By right-clicking while over an existing marker a menu appears, adding options to allow deletion of the marker or to allow all markers of that type to be hidden. Hidden events can be restored to view by selecting Unhide all events from the context menu.

The Information box displays a large range of information pertaining to the dive profile. Normally the Information Box is located to the top left of the Dive Profile panel. If the mouse points outside of the Dive Profile panel, then only the top line of the Information Box is visible (see left-hand part of figure (A) below). The Information Box can be moved around in the Dive Profile panel by click-dragging it with the mouse so that it is not obstructing important detail. The position of the Information Box is saved and used again during subsequent dive analyses.

The moment the mouse points inside the Dive Profile panel, the information box expands and shows many data items. In this situation, the data reflect the time point along the dive profile indicated by the mouse cursor (see right-hand part of figure (B) above where the Information Box reflects the situation at the position of the cursor [arrow] in that image). Therefore, moving the cursor in the horizontal direction allows the Information Box to show information for any point along the dive profile. In this mode, the Information Box gives extensive statistics about depth, gas and ceiling characteristics of the particular dive. These include: Time period into the dive (indicated by a @), depth, cylinder pressure (P), temperature, ascent/descent rate, surface air consumption (SAC), oxygen partial pressure, maximum operating depth, equivalent air depth (EAD), equivalent narcotic depth (END), equivalent air density depth (EADD), decompression requirements at that instant in time (Deco), time to surface (TTS), the calculated ceiling, as well as the calculated ceiling for several Bühlmann tissue compartments.

The user has control over the display of several statistics, represented as four buttons on the left of the profile panel. These are:

Figure (B) above shows an information box with a nearly complete set of data.

Many actions within Subsurface are dependent on a context menu used mostly to manipulate groups of dives. The context menu is found by selecting a dive or a group of dives and then right-clicking.

The context menu is used in many manipulations described below.

Dives are normally numbered incrementally from non-recent dives (low sequence numbers) to recent dives (having the highest sequence numbers). The numbering of the dives is not always consistent. For instance, when non-recent dives are added to the dive list the numbering does not automatically follow on because of the dives that are more recent in date/time than the newly-added dive with an older date/time. Therefore, one may sometimes need to renumber the dives. This is performed by selecting (from the Main Menu) Log → Renumber. Users are given a choice with respect to the lowest sequence number to be used. Completing this operation results in new sequence numbers (based on date/time) for the dives in the Dive List panel.

For regular divers, the dive list can rapidly become very long. Subsurface can group dives into trips. It performs this by grouping dives that have date/times that are not separated in time by more than two days, thus creating a single heading for each diving trip represented in the dive log. Below is an ungrouped dive list (A, on the left) as well as the corresponding grouped dive list comprising five dive trips (B, on the right):

Grouping into trips allows a rapid way of accessing individual dives without having to scan a long lists of dives. In order to group the dives in a dive list, (from the Main Menu) users must select Log → Autogroup. The Dive List panel now shows only the titles for the trips.

The dives in the Dive List panel can be filtered, that is, one can select only some of the dives based on their attributes, e.g. dive tags, dive site, dive master, buddy or protective clothing. For instance, filtering allows one to list the deep dives at a particular dive site, or otherwise the cave dives with a particular buddy.

To open the filter, select Log → Filter divelist from the main menu. This opens the Filter Panel at the top of the Subsurface window. Three icons are located at the top right hand of the filter panel. The Filter Panel can be reset (i.e. all current filters cleared) by selecting the +. The Filter Panel may also be minimised by selecting the middle icon. When minimised, only these three icons are shown. The panel can be maximised by clicking the icon that minimised the panel. The filter may also be reset and closed by selecting the button with the flag. An example of the Filter Panel is shown in the figure below.

Four filter criteria may be used to filter the dive list: dive tags, person (buddy / dive master), dive site and dive suit, each of which is represented by a check list with check boxes. Above each check list is a second-level filter tool, allowing the listing of only some of the attributes within that check list. For instance, typing "ca" in the filter textbox above the tags check list results in the tags check list being reduced to "cave" and "cavern". Filtering of the check list enables the rapid finding of search terms for filtering the dive list.

To activate filtering of the dive list, the check box of at least one item in one of the four check lists needs to be checked. The dive list is then shortened to include only the dives that pertain to the selection criteria specified in the check lists. The four check lists work as a filter with AND operators, Subsurface filters therefore for cave as a tag AND Joe Smith as a buddy; but the filters within a category are inclusive - filtering for cave and boat shows those dives that have either one or both of these tags.

L’export des plongées vers Facebook est géré différemment des autres types d’export. Cela est du au fait que l’export vers Facebook nécessite une connexion vers Facebook, nécessitant un identifiant et un mot de passe. À partir du menu principal, si vous sélectionnez Fichier → Préférences → Facebook, un écran de connexion est présenté (voir l’image A sur la gauche, ci dessous). Entrez vos identifiant et mot de passe Facebook. Une fois connecté à Facebook, le panneau de l’image B ci dessous est présenté. Ce panneau a un bouton qui doit être sélectionné pour fermer la connexion Facebook.

Having established a login to Facebook, transfer of a dive profile to one’s Facebook timeline is easy. A Facebook icon appears in the Notes panel of Subsurface (See image A below). Ensure that the dive that you want to transfer to the timeline is depicted in the Subsurface Dive Profile panel. Select the Facebook icon, and a dialogue is shown, determining the amount of additional information transferred with the dive profile (see image B, below). In order to transfer a dive profile to Facebook, the name of a Facebook album needs to be provided. The checkboxes on the lefthand side allow one to determine how much additional information should be transferred with the dive profile. This information is shown in the text box on the right hand side of the panel (see image B, below). You can easily edit the message that will be posted right there in the text box. Having specified the additional information and verified the text you want to post, select the OK button which triggers the transfer to Facebook. After a while, an acknowledgement dialogue appears, indicating successful transfer to Facebook.

Both the Album created and the post to your time line will be marked as private. In order for friends to be able to see the post you have to change its permissions from a regular Facebook login either in a browser or a Facebook app. While this is an extra step the developers felt that this was the better solution to avoid having unwanted posts in your public timeline.

If required, then close the Facebook connection by either closing Subsurface or by selecting File → Preferences → Facebook from the Main Menu, and clicking the appropriate button on the Facebook Preferences panel.

For non-Facebook exports, the export function can be reached by selecting File → Export, which brings up the Export dialog. This dialog always gives two options: save ALL dives, or save only the dives selected in Dive List panel of Subsurface. Click the appropriate radio button (see images below).

A dive log or part of it can be saved in three formats:

Export to other formats can be achieved through third party facilities, for instance www.divelogs.de.

There are several settings in the Defaults panel:

Here user can choose between metric and imperial units of depth, pressure, volume, temperature and mass. By selecting the Metric or Imperial radio button at the top, users can specify that all units are in the chosen measurement system. Alternatively, if one selects the Personalise radio button, units can be selected independently, with some units in the metric system and others in imperial.

This panel allows two type of selections:

Show: Here users can specify the amount of information shown as part of the dive profile: * Thresholds: Subsurface can display the nitrogen, oxygen and the helium partial pressures during the dive. These are enabled using the toolbar on the left hand side of the *Dive Profile panel. For each of these graphs users can specify a threshold value on the right-hand side of the Preferences panel. If any of the graphs go above this threshold level, the graph is highlighted in red, indicating that the threshold has been exceeded.

Choose a language that Subsurface will use.

A checkbox allows one to use the System Default language which in most cases will be the correct setting; with this Subsurface simply runs in the same language / country settings as the underlying OS. If this is for some reason undesirable users can uncheck this checkbox and pick a language / country combination from the list of included localizations. The Filter text box allows one to list similar languages. For instance there are several system variants of English or French. This particular preference requires a restart of Subsurface to take effect.

This panel facilitates communication between Subsurface and data sources on the Internet.

This is important, for instance, when Subsurface needs to communicate with Internet services such as the Subsurface Companion app or data export/import from Divelogs.de. These Internet requirements are determined by one’s type of connection to the Internet and by the Internet Service Provider (ISP) used. One’s ISP should provide the appropriate information. If a proxy server is used for Internet access, the appropriate information needs to be provided here. The type of proxy needs to be selected from the dropdown list. after which the IP address of the host and the appropriate port number should be provided. If the proxy server uses authentication, the appropriate userID and password also needs to be provided so that Subsurface can automatically pass through the proxy server to access the Internet.

This panel allows one to log into a Facebook account in order to transfer information from Subsurface to Facefook.

If one provides a valid Facebook userID and password, a connection to Facebook is created. The connection to Facebook is closed when one closes down Subsurface. At this point the checkbox labelled "Keep connection to Subsurface", on the login screen has no effect. See the section Exporting dive profiles to Facebook for more information.

Like the Subsurface dive log, the planner screen is divided into several sections (see image below). The setup parameters for a dive are entered into the several sections on the left hand side of the screen. The setup is divided into several sections: Available Gases, Rates, Planning, Gas Options and Notes.

At the top right hand is a green design panel upon which the profile of the dive can be manipulated directly by dragging and clicking as explained below. This feature makes the Subsurface dive planner unique in ease of use.

At the bottom right is a text panel with a heading of Dive Plan Details. This is where the details of the dive plan are provided in a way that can easily be copied to other software. This is also where any warning messages about the dive plan are printed.

The planning is performed in three stages

a) Nitrogen management: This is performed by specifying the rates for descent and ascent, as well as the gradient factors (GFLow and GFHigh) under the headings Rates and Planning to the bottom left of the planning screen. Initially, the GFHigh and GFLow values in the Preferences panel of Subsurface is used. If these are changed within the planner (see Gas Options within the planner), the new values are used without changing the original values in the Preferences. Gradient Factor settings strongly affect the calculated ceilings and their depths. A very low GFLow value brings about decompression stops early on during the dive. ** For more information about Gradient factors, see the section on Gradient Factor Preference settings. For more information external to this manual see:

The ascent rate is critical for nitrogen off-gassing at the end of the dive and is specified for several depth ranges, utilising the average (or mean) depth as a yardstick. The mean depth of the dive plan is indicated by a light grey line on the dive profile. Ascent rates at deeper levels are often in the range of 8-12 m/min, while ascent rates near the surface are often in the range of 4-9 m/min. The descent rate is also specified. If the option Drop to first depth is activated, then the descent phase of the planned dive will be at the maximal descent rate specified in the Rates section of the dive setup.

b) Oxygen management: In the Gas Options part of the dive specification, the maximum partial pressure for oxygen needs to be specified for the bottom part of the dive (bottom po2) as well as for the decompression part of the dive (deco po2). The most commonly used values are 1.4 bar for the bottom part of the dive and 1.6 bar for any decompression stages. Normally, a partial pressure of 1.6 bar is not exceeded. PO2 settings and the depth at which switching to a gas takes place can also be edited in the Available Gases dialog. Normally the planner decides on switching to a new gas when, during ascent, the partial pressure of the new gas has increased to 1.6 bar.

c) Gas management: With open-circuit dives this is a primary consideration. One needs to keep within the limits of the amount of gas within the dive cylinder(s), allowing for an appropriate margin for a safe return to the surface, possibly sharing with a buddy. Under the Gas Options heading, specify the best (but conservative) estimate of your surface-equivalent air consumption (SAC, also termed RMV) in litres/min (for the time being, only SI units are supported). Specify the SAC during the bottom part of the dive (bottom SAC) as well as during the decompression or safety stops of the dive (deco SAC). Values of 15-30 l/min are common. For good gas management, a thumbsuck guess is not sufficient and one needs to monitor one’s gas consumption on a regular basis, dependent on different dive conditions and/or equipment. The planner calculates the total volume of gas used during the dive and issues a warning if one exceeds the total amount of gas available. Good practice demands that one does not dive to the limit of the gas supply but that an appropriate reserve is kept for unforeseen circumstances. For technical diving, this reserve can be up to 66% of the total available gas.

Now (at last) one can start the detailed time-depth planning of the dive. Subsurface offers a unique graphical interface for performing this part of the planning. The mechanics of doing this is similar to hand-entering a dive profile in the dive log part of Subsurface. Upon activating the planner, a default dive of depth 15 m for 40 min is offered in the bue design surface to the top right hand of the screen. The white dots (waypoints) on the profile can be dragged with a mouse. Create more waypoints by double-clicking on the profile line and ensuring that the profile reflects the intended dive. Drag the waypoints to represent the depth and duration of the dive. It is NOt necessary to specify the ascent part of the dive since the planner calculates this, based on the settings that have been specified. If any of the management limits (for nitrogen, oxygen or gas) is exceeded, the surface above the dive profile changes from BLUE to RED.

Each waypoint on the dive profile creates a Dive Planner Point in the table on the left of the dive planner panel. Ensure that the Used Gas value in each row of that table corresponds to one of the gas mixtures specified in the Available Gases table. Add new waypoints until the main features of the dive have been completed, e.g. the bottom time segment and deep stops (if these are implemented). Leave the remaining waypoints on the ascent to Subsurface. In most cases Subsurface computes additional way points in order to fulfill decompression requirements for that dive. A waypoint can be moved by selecting that waypoint and by using the arrow keys. The waypoints listed in the Dive Planner Points dialogue can be edited by hand in order to obtain a precise presentation of the dive plan. In fact, one can create the whole dive profile by editing the Dive Planner Points dialog.

Indicate any changes in gas cylinder used by indicating gas changes as explained in the section hand-creating a dive profile. These changes should reflect the cylinders and gas compositions defined in the table with Available Gases. If two or more gases are used, automatic gas switches will be suggested during the ascent to the surface. However, these changes can be deleted by right-clicking the gas change and by manually creating a gas change by right-clicking on the appropriate waypoint.

A non-zero value in the "CC set point" column of the table of dive planner points indicates a valid setpoint for oxygen partial pressure and that the segment is dived using a closed circuit rebreather (CCR). If the last manually entered segment is a CCR segment, the decompression phase is computed assuming the diver uses a CCR with the specified set-point. If the last segment (however short) is on open circuit (OC, indicated by a zero set-point) the decompression is computed in OC mode. The planner only considers gas changes in OC mode.

Below is an example of a dive plan to 45m using EAN26, followed by an ascent using EAN50 and using the settings as described above.

Once the above has been completed, one can save it by clicking the Save button towards the top middle of the planner. The saved dive plan will appear in the Dive List panel of Subsurface.

The dive plan details

On the bottom right of the dive planner, under Dive Plan Details, the exact details of the dive plan are provided. These details may be modified by checking any of the options under the Notes section of the dive planner, immediately to the left of the Dive Plan Details. If a Verbatim diveplan is requested, a detailed sentence-level explanation of the dive plan is given. If any of the management specifications have been exceeded during the planning, a warning message is printed underneath the dive plan information.

If the option Display segment duration is checked, then the duration of each depth level is indicated in the Dive Plan Details. This duration INCLUDES the transition time to get to that level. However, if the Display transition in deco option is checked, the transitions are shown separately from the segment durations at a particular level.

To plan a dive using a closed circuit rebreather, select the CCR option in the dropdown list, circled in blue in the image below.

Available gases: In the Available gases table, enter the cylinder information for the diluent cylinder and for any bail-out cylinders. Do NOT enter the information for the oxygen cylinder since it is implied when the CCR dropdown selection is made.

Entering setpoints: Specify a default setpoint in the Preferences tab, by selecting File → Preferences → Graph from the main menu. All user-entered segments in the Dive planner points table use the default setpoint value. Then, different setpoints can be specified for dive segments in the Dive planner points table. A zero setpoint means the diver bails out to open circuit mode for that segment. The decompression is always calculated using the setpoint of the last manually entered segment. So, to plan a bail out ascent for a CCR dive, add a one-minute dive segment to the end with a setpoint value of 0. The decompression algorithm does not switch deco-gases automatically while in CCR mode (i.e. when a positive setpoint is specified) but, of course, this is calculated for bail out ascents.

The dive profile for a CCR dive may look something like the image below.

Note that, in the Dive plan details, the gas consumption for a CCR segment is not calculated, so gas consumptions of 0 litres are the norm.

To plan a dive using a passive semi-closed rebreather (pSCR), select pSCR rather than Open circuit in the dropdown list. The parameters of the pSCR diver can be set by selecting File → Preferences → Graph from the main menu, where the gas consumption calculation takes into account the pSCR dump ratio (default 10:1) as well as the metabolism rate. The calculation also takes the oxygen drop accross the mouthpiece of the rebreather into account. If the pO₂ drops below what is considered a save value, a warning appears in the Dive plan details. A typical pSCR configuration is with a single cylinder and one or more bail-out cylinders. Therefore the setup of the Available gases and the Dive planner points tables are very similar to that of a CCR dive plan, described above. However, no oxygen setpoints are specified for pSCR dives. Below is a dive plan for a pSCR dive. The dive is comparable to that of the CCR dive above, but note the longer ascent duration due to the lower oxygen in the loop due to the oxygen drop across the mouthpiece of the pSCR equipment.

Normally, when a dive plan has been saved, it is accessible from the Dive List, like any other dive log. Within the Dive List there is not a way to change a saved dive plan. To perform changes to a dive plan, select it on the Dive List. Then, in the main menu, select Log → Re-plan dive. This will open the selected dive plan within the dive planner, allowing changes to be made and saved as usual.

In addition there is the option "Save new". This keeps the original planned dive and adds a (possibly modified) copy to the dive list. If that copy is saved with the same start time as the original, the two dives are considered two versions of the same dive and do not influence other each during decompression calculation (see next section).

Repetitive dives can easily be planned if the dates and start times of the repetitive dive set is specified appropriately in the top left-hand Start Time field. Subsurface calculates the gas loading figures correctly and the effect of the first dive is evaluated on later dives.

If one has just completed a long/deep dive and is planning another dive, then highlight, in the Dive List, the dive that has just been completed and then activate the planner. Depending on the start time of the planned dive, the planner takes into account the gas loading incurred during the completed dive and allows planning within these limitations.

If only a few standard configurations are used (e.g. in GUE), then a template dive can be created conforming to one of the configurations. If one now wishes to plan a dive using this configuration, just highlight the template dive in the Dive List and activate the planner: the planner takes into account the configuration in the highlighted dive.

Selecting the Print button in the planner allows printing of the Dive Plan Details for wet notes. Alternatively one can cut and paste the Dive Plan Details for inclusion in a text file or word processing document.

Dive plans have many characteristics in common with dive logs (dive profile, dive notes, etc). After a dive plan has been saved, the dive details and gas calculations are saved in the Notes tab. While a dive plan is being designed, it can be printed using the Print button in the dive planner. This prints the dive details and gas calculations in the Dive Plan Details panel of the dive planner. However, after the plan has been saved, it is represented in a way very similar to a dive log and the gas calculations cannot be accessed in the same way as during the planning process. The only way to print the dive plan is to use the File → Print facility on the main menu in the same way as for dive logs or by copy and paste to a word processor.

Sous Mac, les utilisateurs peuvent parfois avoir besoin d’installer manuellement le bon pilote. Par exemple, pour le Mares Puck ou n’importe quel autre ordinateur de plongée utilisant une interface USB-série basé sur le composant Silicon Labs CP2101 ou similaire, le bon pilote est disponible sous Mac_OSX_VCP_Driver.zip sur le dépôt de documents et logiciels Silicon Labs.

Essayez simplement COM1, COM2, etc. La liste déroulante devrait contenir tous les périphériques COM connectés.

La liste déroulante devrait contenir tous les ordinateurs de plongée connectés.

Il existe un moyen sûr de trouver le port :

Un message similaire à celui-ci devrait apparaitre :

La troisième ligne en partant du bas montre que l’adaptateur FTDI USB est détecté et connecté sur ttyUSB3. Cette information peut à présent être utilisée pour les paramètres d’importation en tant que /dev/ttyUSB3 pour que Subsurface utilise le bon port USB.

S’assurer que l’utilisateur possède les droits d'écriture sur le port série USB :

Sur les systèmes similaires à Unix, les ports USB ne peuvent être accédés que par des utilisateurs membres du groupe dialout. Si vous n'êtes pas root, vous n'êtes peut-être pas membre de ce groupe et ne pouvez donc pas utiliser le port USB. Si votre nom d’utilisateur est johnB :

En tant que root, tapez : usermod -a -G dialout johnB+ (utilisateurs d’Ubuntu : sudo usermod -a -G dialout johnB) Cela ajoute johnB au groupe dialout. Tapez : id johnB Cela liste tous les groupes auquel johnB appartient et vérifiez que l’appartenance au groupe est bien effectif. Le groupe dialout devrait être listé parmi les différents IDs. Sous certaines circonstances, les modifications ne prennent effet qu’après une déconnexionpuis reconnexion sur l’ordinateur (sous Ubuntu, par exemple). Avec le bon nom de périphérique (par exemple dev/ttyUSB3) et avec un accès en écriture au port USB, l’ordinateur de plongée devrait se connecter et vous devriez pouvoir importer vos plongées.

For Bluetooth pairing of the dive computer, refer to the manufacturer’s user guide. When using a Shearwater Predator/Petrel, select Dive Log → Upload Log and wait for the Wait PC message.

Bluetooth is most likely already enabled. For pairing with the dive computer choose Control Panel → Bluetooth Devices → Add Wireless Device. This should bring up a dialog showing your dive computer (in Bluetooth mode) and allowing pairing. Right click on it and choose Propertie s→ COM Ports to identify the port used for your dive computer. If there are several ports listed, use the one saying "Outgoing" instead of "Incoming".

For downloading to Subsurface, the Subsurface drop-down list should contain this COM port already. If not, enter it manually.

Note: If there are issues afterwards when downloading from the dive computer using other software, remove the existing pairing with the dive computer.

Click on the Bluetooth symbol in the menu bar and select Set up Bluetooth Device…. The dive computer should then show up in the list of devices. Select it and go through the pairing process. This step should only be needed once for initial setup.

Once the pairing is completed the correct device is shown in the Device or Mount Point drop-down in the Subsurface Import dialog.

Ensure Bluetooth is enabled on the Subsurface computer. On most common distributions this should be true out of the box and pairing should be straight forward. For instance, Gnome3 shows a Bluetooth icon in the upper right corner of the desktop where one selects Set up New Device. This should show a dialog where one can select the dive computer (which already should be in Bluetooth mode) and pair it. If a PIN is required, try manually setting 0000.

In the rare cases where the above is not true, then depending on your system, try initd or systemd. This might be different and also involve loading modules specific to your hardware. In case your system is running systemd, manually run systemctl start bluetooth.service to enable it, in case of initd, run something like rc.config start bluetoothd or /etc/init.d/bluetooth start.

One may also use a manual approach by using such commands:

Unfortunately on Linux binding to a communication device has to be done manually by running:

For downloading dives in Subsurface specify the device name connected to the MAC address in the last step above, e.g. /dev/rfcomm0.

After selecting the above device name, download the dives from the Uemis Zurich. One technical issue with the Uemis Zurich download implementation (this is a Uemis firmware limitation, not a Subsurface issue) is that one cannot download more than about 40-50 dives without running out of memory on the SDA. This will usually only happen the very first time one downloads dives from the Uemis Zurich. Normally when downloading at the end of a day or even after a dive trip, the capacity is sufficient. If Subsurface displays an error that the dive computer ran out of space the solution is straight forward. Disconnect the SDA, turn it off and on again, and reconnect it. You can now retry (or start a new download session) and the download will continue where it stopped previously. One may have to do this more than once, depending on how many dives are stored on the dive computer.

After executing this command, Subsurface will recognise the Galileo dive computer and download dive information.

Under Windows, a similar situation exists. Drivers for the MCS7780 are available from some Internet web sites e.g. www.drivers-download.com.

For the Apple Mac, IrDA communication via the MCS7780 link is not available for OSX 10.6 or higher.

Subsurface accesses the .txt and the .csv files to obtain dive log information.

The APD dive log will appear within Subsurface.

Divemanager 3 (DM3):

Divemanager 4 (DM4) and Divemanager 5 (DM5):

DM4 and DM5 use identical mechanisms for exporting dive logs. To export a divelog from Divemanager one needs to locate the DM4/DM5 database where the dives are stored. the user can either look for the original database or make a backup of the dives. Both methods are described here.

Locating the Suunto DM4 (or DM5) database:

Making a backup copy of the Suunto DM4/DM5 database:

These are open source spreadsheet applications forming parts of larger open source office suite applications. The user interaction with LibreOffice and OpenOffice is very similar. In Libreoffice Calc the time format should be set to minutes:seconds - [mm]:ss and dates should be set to one of: yyyy-mm-dd, dd.mm.yyyy, mm/dd/yyyy. A typical dive log may look like this:

To export the data as a .CSV file from within LibreOffice click File → Save As. On the dialogue that comes up, select the Text CSV (.csv) as the file type and select the option Edit filter settings.

After selecting Save, select the appropriate field delimiter (choose Tab to prevent conflicts with the comma when using this as a decimal point), then select OK.

One can double check the .CSV file by opening it with a text editor, and then import the dive data as explained on the section Importing CSV dives.

The field delimiter (called "list separator" in Microsoft manuals) is not accessible from within Excel and needs to be set through the Microsoft Control Panel. After changing the separator character, all software on the Windows machine use the new character as a separator. One can change the character back to the default character by following the same procedure, outlined below.

Below is an image of the Control Panel:

To export the dive log in CSV format:

With the dive log opened in Excel, select the round Windows button at the top left, then Save As.

Click on the left-hand part of the Save as option, NOT on the arrow on the right-hand. This brings up a dialogue for saving the spreadsheet in an alternative format. From the dropdown list at the bottom of the dialogue, marked Save as Type:, select CSV(Comma delimited) (*.CSV). Ensure that the appropriate folder has been selected to save the CSV file into.

Select the Save button. The CSV-formatted file is saved into the folder that was selected. One can double check the .CSV file by opening it with a text editor, and then import the dive data as explained on the section Importing CSV dives.

Question: I dived with a 12.2 l tank, starting with 220 bar and ending with 100 bar, and I calculate a different SAC compared what Subsurface calculates. Is Subsurface miscalculating?

Answer: Not really. What happens is that Subsurface actually calculates gas consumption differently - and better - than you expect. In particular, it takes the incompressibility of the gas into account. Traditionally, Gas consumption and SAC should be: consumption = tank size x (start pressure - end pressure)

and that’s true for an ideal gas, and it’s what you get taught in dive theory. But an "ideal gas" doesn’t actually exist, and real gases actually don’t compress linearly with pressure. Also, you are missing the fact that one atmosphere of pressure isn’t actually one bar. So the real calculation is:

consumption = (amount_of_air_at_beginning - amount_of_air_at_end)

where the amount of air is not just "tank size times pressure in bar". It’s a combination of: "take compressibility into account" (which is a fairly small issue under 220 bar - you’ll see more differences when you do high-pressure tanks with 300bar) and "convert bar to atm" (which is the majority of your discrepancy). Remember: one ATM is ~1.013 bar, so without the compressibility, your gas use is:

12.2*((220-100)/1.013)

which is about 1445, not 1464. So there was 19 l too much in your simple calculation that ignored the difference between 1 bar and one ATM. The compressibility does show up above 200 bar, and takes that 1445 down about eight litres more, so you really did use only about 1437 l of air at surface pressure.

So be happy: your SAC really is better than your calculations indicated. Or be sad: your cylinder contains less air than you thought it did. And as mentioned, the "contains less air than you thought it did" really starts becoming much more noticeable at high pressure. A 400 bar really does not contain twice as much air as a 200 bar one. At lower pressures, air acts pretty much like an ideal gas.

Subsurface ends up ignoring surface time for many things (average depth, divetime, SAC, etc). Question: Why do dive durations in my dive computer differ from that given by Subsurface?

Answer: For example, if you end up doing a weight check (deep enough to trigger the "dive started") but then come back up and wait five minutes for your buddies, your dive computer may say that your dive is 50 minutes long - because you have fifty minutes worth of samples - but subsurface will say it’s 45 minutes - because you were actually diving for 45 minutes. It’s even more noticeable if you do things like divemastering the initial OW dives, when you may stay in the water for a long time, but spend most of it at the surface. And then you don’t want that to count as some kind of long dive”.