This is a depiction of the potential travel method, according to the specified measures.

The drop-down menu allows you to switch between a people or kilometre view.

The middle circle shows the modes of transport distribution in outline (active travel, public transport, car). The outer circle shows the same kind of information but broken down into sub modes of transport (such as a company car or speed pedelec)

This is a representation of the totals per travel method in the current and new situation, given the set measures.

The drop-down menu allows you to switch between a people or kilometre view.

This is a display of travel methods per distance category, taking into account any measures set. Display is optionally in kilometres or minutes, where limit values can be set.

This is a representation of the potential changes in travel method as a result of the measures taken.

This indicator shows the total annual CO₂ emissions per mode of transport in tonnes per year, before and after the set measures.

Source data CO₂ emissions

This indicator shows the potential savings from different policies put in place on total CO₂ emissions. When allocating to policy areas, the saving effect of working from home is identified first, followed by the effect of modality changes.

This indicator shows the total annual CO₂ emissions per FTE, before and after the set measures.

In order to make CO₂ emissions easy to compare, a classification of ascending sustainability classes (label G to A) is used.

1. A: less than 1125 kg
2. B: 1125-2250 kg
3. C: 2250-3375 kg
4. D: 3375-4500 kg
5. E: 4500-5625 kg
6. F: 5625-6750 kg
7. G: more than 6750 kg

This indicator shows the costs for the residual carbon footprint after measures. There are several ways to look at emissions-related costs:

• Some organizations opt for compensation programs that invest in projects that reduce CO₂ emissions elsewhere, for example by planting trees. The costs shown are based on the Gold Standard of, among others, WWF.
• Other organisations choose to express CO₂ costs based on European emissions trading. The costs shown here are based on the EU Carbon Price Tracker (see for example https://ember-climate.org/data/data-tools/carbon-price-viewer Opent in nieuw tabblad ).
• Organisations that choose to capture and store their CO₂ emissions will find an estimate of the associated costs here. These costs strongly depend on the chosen provider and solution.

The values used in the calculation can be changed in the settings screen.

This indicator shows a breakdown of the organisation's total annual CO₂ emissions from commuting in the current situation.

The annual distance traveled is shown for each mode of transport, along with the average emissions per kilometre and the total annual emissions.

Source data CO₂ emissions

This indicator shows a breakdown of the organisation's total annual CO₂ emissions from commuting, based on set measures.

The annual distance traveled is shown for each mode of transport, along with the average emissions per kilometre and the total annual emissions.

Source data CO₂ emissions

This indicator shows CO₂ reports available to your organisation. They show CO₂ information from your mobility scan in the specific form and scope that matches the report in question. Reports are based on the current situation, without taking into account any set measures.

Click on the report of your choice to open it.

This indicator shows the annual variable commuting costs, based on the stated mileage allowances per mode of transport. It shows the level of costs before and after measures. Fixed costs, such as leasing contracts, are not included. MobilityAnalyst only supports fixed costs per kilometre and does not (yet) support scales or limit values.

This indicator shows the annual variable commuting costs per FTE, based on the stated mileage allowances per mode of transport. It shows the level of costs before and after measures. Fixed costs, such as leasing contracts, are not included. MobilityAnalyst only supports fixed costs per kilometre and does not (yet) support scales or limit values.

This indicator shows the annual variable commuting costs per mode of transport, based on the mileage allowances per mode of transport. It shows the level of costs before and after measures. Fixed costs, such as for lease contracts, are not included. MobilityAnalyst only supports fixed costs per kilometre and does not (yet) support scales or limit values.

The average cost of a parking space for the organisation varies greatly and depends on the location (inner-city or suburbian) and nature (garage or grounds). It is estimated that the average cost is € 700 per year.

Whether these savings can actually be achieved and in what time frame depends on several factors: is parking private or shared, and can parking places be easily divested?

The savings from reducing absence days vary considerably and depend on factors such as salary levels, the nature of the work, the need and ability to immediately replace absence, and the likelihood of lost turnover. On average, costs are estimated at €300 per absence day. If you want to use a different value, please adjust the value shown.

Office cost savings from increased home working vary considerably and depend on several factors. For instance, savings will be greater with structurally lower weekly occupancy, than when home working mainly happens on one specific day (e.g. Friday). Savings can include cost items such as buildings, infrastructure, staff and organisation, IT and administration.

You can decide which cost per workplace you want to calculate with. The default value given is based on theOccupier Cost Index from property consultant Colliers Opent in nieuw tabblad. This compared the office costs of 3,900 buildings in 28 countries according to the European facilities standard EN 15221-4.

This indicator shows the number of parking spaces required on an average day. This does not take into account a disproportionate week schedule or parking spaces for visitors or, for example, shared cars.

This indicator shows the number of bicycle parking spaces required on an average day (including shared bicycles). This does not take into account a disproportionate week schedule or bicycle parking spaces for visitors.

Although each situation is different and the number of charging stations depends, for example, on the number of electric company cars and the number of people and visitors you want to facilitate, there are some rules of thumb.

The indicator shown is based on the advice to offer one charging point per 10 parking spaces (note: Many charging stations contain 2 or more charging points). This standard corresponds to the EU decision as part of the package Clean Energy for All EuropeansOpent in nieuw tabblad.

According to this measure at all new or converted commercial premises 1 charging point per 10 parking spaces should be installed.

This indicator shows the number of people present at the work location on an average day. This does not take into account a non-proportional week level.

This indicator shows the number of days per week a person is present at the work location on average and the change in this as a result of set homeworking policy.

This indicator shows the number of people who can work remote according to set measures, and live near a coworking office of one of the major national providers. For each provider, the table shows the number of people living within a 5 km radius of one of their coworking locations.

This indicator shows the total annual commuting time of all people before and after measures. The commuting time calculations include the total times from door to door, which means:

• Car journey times consist of the average driving time of the outward journey and return journey plus the time required to park the car.
• Public transport travel times consist of travel time according to current timetables, including transfer times and the time required to go from home to the public transport stop and from the public transport stop to the destination.
• Cycling travel times include the cycling time over the fastest door-to-door bike route plus the time needed to park the bike.

This indicator shows the average one-way travel time per FTE, before and after measures. The travel time is based on the mode of transport in accordance with the selected measures, taking into account any (extra) work-from-home days and weighted by the FTE factor so that a person who is present at the office for more days weighs more heavily in the average than a person with less presence.

Total times are calculated door-to-door, meaning:

• Car journey times consist of the average driving time of the outward journey and return journey plus the time required to park the car.
• Public transport travel times consist of travel time according to current timetables, including transfer times and the time required to go from home to the public transport stop and from the public transport stop to the destination.
• Cycling travel times include the cycling time over the fastest door-to-door bike route plus the time needed to park the bike.

This overview visualizes the individual changes per one-way journey and shows how many people have their commuting time affected in what way, either for better or for worse, as a result of the specified measures.

Move the mouse over the graph for details.

This graph shows the number of people divided per 15 minutes of one-way journey time, i.e. the number of people who, for example, have a travel time between 0 and 15 minutes before (grey) and after (blue) measures.

This indicator shows the total annual distance travelled for commuting, taking into account the travel distances associated with the relevant travel method (i.e. cyclists calculated on cycling routes, etc.), before and after measures. This indicator is strongly influenced by homeworking measures.

This indicator shows the average one-way journey distance per mode of transport, based on set measures. This is an unweighted average across all people, without taking into account the number of travel days per person.

This indicator shows the annual calories burned as a result of active travel. This only includes commutes walked or cycled from door-to-door. Calculations are made with an average of 25 kcal per kilometre.

This indicator shows the Big Mac equivalent of the kilocalories burned is also included. According to McDonald's, a Big Mac contains 525 kcal or 2196 kJ.

Several studies have shown that people who cycle to work call in sick less often on average. The average number of sick-leave days for cyclists is 7.4 compared to 8.7 for non-cyclists. Among cyclists, there is a larger group who never call in sick. The frequency of absenteeism among cyclists is also lower than that of non-cyclists.

More information?

• Preventive Medicine: The association between commuter cycling and sickness absence Opent in nieuw tabblad (English)
• Institue for employment-studies: Impact of the Cycle to Work Scheme Opent in nieuw tabblad (English)
• TNO: Fietsen is groen, gezond en voordelig Opent in nieuw tabblad (Dutch)
• Nationaler Radverkehrsplan: Forschung Radverkehr Opent in nieuw tabblad (German)

This indicator shows the proportion of people who achieve the physical activity guidelines just by commuting (by walking or cycling). These guidelinges have been defined by the World Health Organization (WHO) and have been translated to local, national guidelines. For adults, the main recommendations are:

• Physical activity has significant health benefits for hearts, bodies and minds.
• Do at least 150 minutes of moderate-intensity aerobic physical activity per week, like walking and cycling, spread out during the week. Longer activity, more often and at higher intensity, provides additional health benefits.
• Do muscle- and bone-strengthening activities at least twice a week.
• Limit the amount of time spent being sedentary.

The percentage shown is the share of people walking or cycling more than 150 minutes per week for their commute.

Source: WHO Physical Activity Opent in nieuw tabblad

This is a representation of the indicative subdivision of the different forms of active travel in the new situation, based on the following assumptions: For distances up to 1.5 km, we assume walking. For distances up to 1.5 km we assume walking. For distances from 1.5 km to 5 km, we assume a regular (city) bicycle, for distances from 5 to 15 km an e-bike and above that a speed pedelec.

The percentages shown are relative to the total number of people who travel with active travel, accordance to set measures.

Move the mouse over the graph for details.

This indicator shows the annual time spent on active travel. This only includes commutes walked or cycled from door to door.

This is a representation of the potential travel mode, as per set policy, including any overlap between cycling potential and public transport potential. The shaded area shows cyclists who can also travel by public transport, and thus have multiple alternatives to travelling by car.

In addition to commuting time, the number of transfers is an important indicator of the quality of a public transport connection. This indicator shows the average number of transfers in the fastest public transport connection for all people who travel by public transport, according to the set measures.

This includes all transfers between public transport connections (i.e. train-train or train-bus), and not car-train or, for example, train-bicycle.

Note: If people already travel by public transport, they will continue to do so, regardless of the set maximum number of transfers. Multiple transfers are already acceptable for those travelers at the moment and it would be illogical that they no longer travel by public transport as a result of the measure. As a result, the average number of transfers may exceed the set maximum number of transfers.

This indicator shows the weekly number of public transport commutes during peak hours, before and after measures.

This indicator shows the number of public transport commuters who use the train and shows a list of used disembarkation stations, in accordance with (possible) measures. These are the last used train stations in the public transport chain.

This indicator shows the number of public transport commuters using the combination public transport and car (P+R) and shows a list of used P+R facilities in accordance with the set measures.

This indicator shows, if known, the distribution by fuel types of cars and motorcycles used, taking into account any set measures.

The dropdown menu can be used to switch between displaying vehicle numbers or kilometre numbers, and for displaying any company cars.

The middle circle shows the mainline fuel distribution (fossil, electric and unknown). The outer circle shows the same information broken down by detailed fuel types.

This indicator shows the number of company cars, according to the data provided and the potential. This is influenced by the car measure 'discontinue company cars'. Without this measure, MobilityAnalyst will not change company cars.

This indicator shows the number of car journeys (one way) on an average working day that can be saved by the set measures.

Car journeys to the station are considered part of a public transport journey and are not counted as a car journey.

This indicator shows the weekly number of car commutes during peak hours, before and after measures.

This indicator shows the number of hours that an average driver loses per year as a result of traffic congestion, calculated by comparing the individual peak commuting times with off-peak commuting times.

Carpooling can offer a solution for groups of people for whom cycling and public transport are less suitable means of commuting. If these drivers share a ride with each other, this can help reduce costs, CO₂ emissions and commuting time.

A person is included in the carpool potential if they:

• still travel by car after measures and
• live more than 10 km away from the destination and
• there is a colleague who lives less than 3 kilometres away and is traveling to the same destination by car.

MobilityAnalyst provides various regional analysis capabilities for many regions. These capabilities provide insight into trips from certain areas of origin, past certain analysis points or to certain destination areas. These areas and points are predefined, often in consultation with a regional partner.

The analysis points help to gain insight into road use at certain bottlenecks in the road network or crowds on public transport routes. The number of commutes per section is shown before and after measures, in order to investigate the effectiveness of, for example, measures to avoid rush-hour and road works.

The origin and destination areas help, for example, to gain insight into where groups of employees of an organisation or region come from.

Note: if you want to zoom in on the characteristics of persons passing such an analysis point or travelling from/to such an area, it is possible to make a selection of those persons with the filter settings.