Manual controls In the first half of the twentieth century, almost all elevators had no automatic positioning of the floor on which the cab would stop. Some of the older freight elevators were controlled by switches operated by pulling on adjacent ropes. In general, most elevators before WWII were manually controlled by
elevator operators using a
rheostat connected to the motor. This rheostat (see picture) was enclosed within a cylindrical container about the size and shape of a cake. This was mounted upright or sideways on the cab wall and operated via a projecting handle, which was able to slide around the top half of the cylinder. The elevator motor was located at the top of the shaft or beside the bottom of the shaft. Pushing the handle forward would cause the cab to rise; backwards would make it sink. The harder the pressure, the faster the elevator would move. The handle also served as a
dead man switch: if the operator let go of the handle, it would return to its upright position, causing the elevator cab to stop. In time, safety interlocks would ensure that the inner and outer doors were closed before the elevator was allowed to move. This lever would allow some control over the energy supplied to the motor and so enabled the elevator to be accurately positioned—if the operator was sufficiently skilled. More typically, the operator would have to "jog" the control, moving the cab in small increments until the elevator was reasonably close to the landing point. Then the operator would direct the outgoing and incoming passengers to "watch the step". The Otis
Autotronic system of the early 1950s brought the earliest predictive systems which could anticipate traffic patterns within a building to deploy elevator movement in the most efficient manner. Relay-controlled elevator systems remained common until the 1980s; they were gradually replaced with solid-state systems, and
microprocessor-based controls are now the industry standard. Most older, manually operated elevators have been retrofitted with automatic or semi-automatic controls.
General controls A typical modern passenger elevator will have: • Outside the elevator, buttons to go up or down (the bottom floor only has the up button, the top floor only has the down button, and every floor in between (usually) has both) • Space to stand in, guardrails, seating cushion (luxury) • Overload sensor – prevents the elevator from moving until excess load has been removed. It may trigger a voice prompt or buzzer alarm. This may also trigger a "full car" indicator, indicating the car's inability to accept more passengers until some are unloaded. • Electric fans or air conditioning units to enhance circulation and comfort. • A control panel with various buttons. In many countries, button text and icons are raised to allow blind users to operate the elevator; many have
Braille text besides. Buttons include: • Call buttons to choose a floor. Some of these may be key switches (to control access). In some elevators, such as those in some hotels, certain floors are inaccessible unless one swipes a security card or enters a passcode. • An alarm button or switch, which passengers can use to warn the premises manager that they have been trapped in the elevator. Some elevators also have emergency telephones to summon help in the event of entrapment. In many jurisdictions this is required by law. • Door open and door close buttons. The operation of the door open button is transparent, immediately opening and holding the door, typically until a timeout occurs and the door closes. The operation of the door close button is less transparent, and it often appears to do nothing, leading to frequent but incorrect reports that the door close button is a
placebo button: either not wired up at all, or inactive in normal service. On many older elevators, if one is present, the door close button is functional because the elevator is not ADA compliant and/or it does not have a fire service mode. Working door open and door close buttons are required by code in many jurisdictions, including the United States, specifically for emergency operation: in independent mode, the door open and door close buttons are used to manually open or close the door. Beyond this, programming varies significantly, with some door close buttons immediately closing the door, but in other cases being delayed by an overall timeout, so the door cannot be closed until a few seconds after opening. In this case (hastening normal closure), the door close button has no effect. However, the door close button will cause a hall call to be ignored (so the door will not reopen), and once the timeout has expired, the door close will immediately close the door, for example, to cancel a door open push. The minimum timeout for automatic door closing in the US is 5 seconds, which is a noticeable delay if not over-ridden. • A set of doors kept locked on each floor to prevent unintentional access into the elevator shaft by the unsuspecting individual. The door is unlocked and opened by a machine sitting on the roof of the car, which also drives the doors that travel with the car. Door controls are provided to close immediately or reopen the doors, although the button to close them immediately is often disabled during normal operations, especially on more recent elevators. Objects in the path of the moving doors will either be detected by sensors or physically activate a switch that reopens the doors. Otherwise, the doors will close after a preset time. Some elevators are configured to remain open at the floor until they are required to move again. Regulations often require doors to close after use to prevent smoke from entering the elevator shaft in event of fire. • A stop switch to halt the elevator while in motion, which is often used to hold an elevator open while freight is loaded. Keeping an elevator stopped for too long may set off an alarm. Unless local codes require otherwise, this will most likely be a
key switch. Some elevators may have one or more of the following: • text for visually impaired people and a button illuminates to alert a hearing impaired person that the alarm is ringing and the call is being placed.An
elevator telephone, which can be used (in addition to the alarm) by a trapped passenger to call for help. This may consist of a transceiver, or simply a button. This feature is often required by local regulations. • Hold button: This button delays the door closing timer, useful for loading freight and hospital beds. • Call cancellation: A destination floor may be deselected by double clicking. • Access restriction by key switches, RFID reader, code keypad, hotel room card, etc. • One or more additional sets of doors. This is primarily used to serve different floor plans: on each floor only one set of doors opens. For example, in an elevated crosswalk setup, the front doors may open on the street level, and the rear doors open on the crosswalk level. This is also common in garages, rail stations, and airports. Alternatively, both doors may open on a given floor. This is sometimes timed so that one side opens first for getting off, and then the other side opens for getting on, to improve boarding/exiting speed. This is particularly useful when passengers have luggage or carts, as at an airport, due to reduced maneuverability. • In case of dual doors, there may be two sets of door open and door close buttons, with one pair controlling the front doors, from the perspective of the console, typically denoted <> and ><, with the other pair controlling the rear doors, typically denoted with a line in the middle, <|> and >|<, or double lines, |<>| and >||<. This second set is required in the US if both doors can be opened at the same landing, so that the doors can both be controlled in independent service. • Security camera • Plain walls or mirrored walls • Glass windowpane providing a view of the building interior or onto the streets An audible signal button, labeled "S": in the US, for elevators installed between 1991 and 2012 (initial passage of ADA and coming into force of 2010 revision), a button which if pushed, sounds an audible signal as each floor is passed, to assist visually impaired passengers. This button is no longer used on new elevators, where the sound is normally obligatory. Other controls, which are not available for the public (either because they are
key switches, or because they are kept behind a locked panel), include: • Fireman's service, phase II key switch • Switch to enable or disable the elevator. • An ''inspector's'' switch, which places the elevator in inspection mode (this may be situated on the top of the elevator) • Manual up/down controls for elevator technicians, to be used in inspection mode, for example. • An
independent service/
exclusive mode (also known as "car preference"), which will prevent the car from answering to hall calls and only arrive at floors selected via the panel. The door should stay open while parked on a floor. This mode may be used for temporarily transporting goods. • Attendant service mode • Large buildings with multiple elevators of this type also had an
elevator dispatcher stationed in the lobby to direct passengers and to signal the operator to leave with the use of a mechanical "cricket" noisemaker.
External controls Elevators are typically controlled from the outside by a call box, which has up and down buttons, at each stop. When pressed at a certain floor, the button (also known as a "hall call" button) calls the elevator to pick up more passengers. If the particular elevator is currently serving traffic in a certain direction, it will only answer calls in the same direction unless there are no more calls beyond that floor. In a group of two or more elevators, the call buttons may be linked to a central dispatch computer, such that they illuminate and cancel together. This is done to ensure that only one car is called at one time. Key switches may be installed on the ground floor so that the elevator can be remotely switched on or off from the outside. In destination control systems, one selects the intended destination floor (in lieu of pressing
"up" or
"down") and is then notified which elevator will serve their request.
Floor numbering To distinguish between floors, the different landings are given numbers and sometimes letters. See the above article for more information.
Elevator algorithm The
elevator algorithm, a simple
algorithm by which a single elevator can decide where to stop, is summarized as follows: • Continue traveling in the same direction while there are remaining requests in that same direction. • If there are no further requests in that direction, then stop and become idle, or change direction if there are requests in the opposite direction. The elevator algorithm has found an application in computer
operating systems as an algorithm for scheduling
hard disk requests. Modern elevators use more complex
heuristic algorithms to decide which request to service next. In taller buildings with high traffic, such as the
New York Marriott Marquis or the
Burj Khalifa, the
destination dispatch algorithm is used to group passengers going to similar floors, maximizing load by up to 25%.
Destination control system in Boston, United States Some skyscraper buildings and other types of installation feature a destination operating panel where a passenger registers their floor calls before entering the car. The system lets them know which car to wait for, instead of everyone boarding the next car. In this way, travel time is reduced as the elevator makes fewer stops for individual passengers, and the computer distributes adjacent stops to different cars in the bank. Although travel time is reduced, passenger waiting times may be longer as they will not necessarily be allocated the next car to depart. During the down peak period the benefit of destination control will be limited as passengers have a common destination. It can also improve accessibility, as a mobility-impaired passenger can move to their designated car in advance. Inside the elevator there is no call button to push, or the buttons are there but they cannot be pushed—except door opening and alarm button—they only indicate stopping floors. The idea of destination control was originally conceived by
Leo Port from Sydney in 1961, but at that time elevator controllers were implemented in relays and were unable to optimize the performance of destination control allocations. The system was first pioneered by
Schindler Elevator in 1992 as the Miconic 10. Manufacturers of such systems claim that average traveling time can be reduced by up to 30%. However, performance enhancements cannot be generalized as the benefits and limitations of the system are dependent on many factors. One problem is that the system is subject to gaming. Sometimes, one person enters the destination for a large group of people going to the same floor. The dispatching
algorithm is usually unable to completely cater for the variation, and latecomers may find the elevator they are assigned to is already full. Also, occasionally, one person may press the floor multiple times. This is common with up/down buttons when people believe this to be an effective way to hurry elevators. However, this will make the computer think multiple people are waiting and will allocate empty cars to serve this one person. To prevent this problem, in one implementation of destination control, every user is given an
RFID card, for identification and tracking, so that the system knows every user call and can cancel the first call if the passenger decides to travel to another destination, preventing empty calls. The newest invention knows even where people are located and how many on which floor because of their identification, either for the purposes of evacuating the building or for security reasons. Another way to prevent this issue is to treat everyone traveling from one floor to another as one group and to allocate only one car for that group. The same destination scheduling concept can also be applied to public transit such as in
group rapid transit. control station, outside of the car, on which the user presses a button to indicate the desired destination floor, and the panel indicates which car will be dispatched ==Special operating modes==