| Revision as of 01:57, 11 December 2005 edit24.64.112.236 (talk)No edit summary← Previous edit | Latest revision as of 05:31, 9 September 2017 edit undoSteel1943 (talk | contribs)Autopatrolled, Extended confirmed users, Page movers, Pending changes reviewers, Rollbackers, Template editors197,090 edits #REDIRECT Security alarm#Design {{R with history}} {{R to section}} - subject is not notable independent of the subject security alarm | ||
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| A '''burglar alarm control panel''' is a panel that is used to control a ]. | |||
| {{R with history}} {{R to section}} | |||
| The simplest type of burglar alarm control consists of one relay. In this type, the | |||
| sensor circuit (called the ''loop'' in industrial terminology) holds a relay energized. | |||
| Since the path for the loop goes through a set of contacts which are normally open (when | |||
| the relay is restored they are open, when the relay is energized they are closed), when the | |||
| loop opens, even momentarily, the relay will drop out and stay that way. A second set of | |||
| contacts on the relay, normally closed (when the relay is restored they are closed, when | |||
| the relay is energized they are open) is used to operate the annunciator, usually a bell. | |||
| The system is disarmed by a key operated shunt which forces the relay to energize, and is | |||
| armed by closing all traps and then by opening the key operated shunt. While burglar alarm | |||
| controls are now very elaborate, the single-relay control incorporates all the functionality | |||
| of any control. These controls and a closely related dual-relay design are still widely used | |||
| in stand-alone applications, powered by carbon cells. | |||
| In a modern full-functional control there are two, possibly three classifications of | |||
| loop, and each classification of loop has two types. The classifications of loop are | |||
| ''instant'' and ''delay'', and ''day'' loops. The types of loops are single-circuit and | |||
| double-circuit. In modern controls there may be several instant and/or day loops, but there | |||
| is usually only one delay loop. Depending on the control, any loop may be single-circuit | |||
| or double-circuit. | |||
| The loop types will be discussed first. If we refer to the prototypical single-relay | |||
| control, the current comes from the battery on the positive or ''high'' side, goes through | |||
| the relay and the latching circuit, and then back to the battery on the negative or ''low'' | |||
| side. Since the loop is a series circuit (all contacts are closed when the points they are | |||
| protecting are secured and they are therefore wired into a series circuit) there are two | |||
| places in the circuit where the loop can be inserted. The loop can be inserted on the high | |||
| side, between the battery and the relay, or it may be inserted on the low side, between the | |||
| relay and the return. If the loop is taken out to the protection only once, then the system | |||
| is a single-loop system and the other side of the loop is simply strapped at the control. If | |||
| both the high side and the low side of the loop are taken out to the protection, then the | |||
| system is a double-loop system. | |||
| The advantage of the single loop system is lower cost and lower complexity. However, | |||
| the disadvantage of the single loop system used in our example is that by strapping across | |||
| the contact, an intruder could open a hole in the protection and thereby defeat the system. | |||
| The double loop system, while it is more expensive, does not have this disadvantage, as an | |||
| attempt to strap across the contact can also strap across the relay, dropping it out and | |||
| tripping the system. | |||
| The three classifications of loops as mentioned above are instant, delay, and day | |||
| circuits. In our example there is only one loop, the instant loop. Not all controls have | |||
| all classifications of loops. | |||
| The ''instant'' loop is armed as soon as the control is armed, and any loop violation, | |||
| no matter how transient, will cause an immediate trip. | |||
| The ''delay'' loop, found primarily in controls designed for use with keystations | |||
| located within the protected area, does not arm as soon as the control is armed. Instead, | |||
| there is a delay of nominally 45 seconds before this loop arms, to allow the person arming | |||
| the control time to clear the protected area. Also, when the protected point covered by the | |||
| delay loop is opened, the control will not go into alarm for nominally 45 seconds, to allow | |||
| the person entering time to go to the keystation and disarm the system. | |||
| The ''day'' loop is a supervisory circuit for protection such as window bugs, tampers, | |||
| and window foil. If this loop is violated when the control is armed the result will be that | |||
| the system will trip and the control goes into alarm. If this loop is violated when the control | |||
| is not armed the result will be that a supervisory alarm, or ''trouble'' alarm will be | |||
| signaled. | |||
| Modern alarm controls are solid-state devices and do not use relays. The front end | |||
| for the loop is usually a double op-amp comparator sensing a current flow through the | |||
| protection. Because the loop resistance can be up to a couple of hundred ohms at installation, | |||
| and because resistance transients can occur which are not the result of a loop violation, there | |||
| is usually a fair bit of tolerance as to the limits of the current flow which are considered | |||
| normal operation. The current is set by an end-of-line resistor located at the contact for the | |||
| point being protected. If the loop is opened, the current will decrease to zero and the control | |||
| will go into alarm. If the contact is strapped across, the current will increase (the control | |||
| incorporates current limiting to prevent damage) and the control will go into alarm. | |||
| Early (c.a. 1980) solid-state alarm controls used shunt switches or momentary closures on | |||
| the key circuit to arm or disarm the control. Modern controls can use these arming techniques, | |||
| but more frequently use a keypad which sends operating information to the control. Thus, there | |||
| is no point in attacking the keypad, as there is no intelligence in the keypad, it is all located | |||
| in the control. Also, many controls feature integrated transmitters, using wired telephony or | |||
| optionally, cellular telephony. These controls also monitor the status of the telephone line, | |||
| and can be programmed to trip if the telephone line fails (or is cut). The controls which utilize | |||
| cellular telephony report either periodically or at a pseudo-random interval to the central | |||
| station, and a failure to report will result in a dispatch. | |||
| High-security alarm controls use current and impedance monitoring on the premises, and may | |||
| report to the central station via dedicated voice-grade or DC (obsolescent) circuit, or by means | |||
| of multiple-drop AC grade transmitter (multiplex). | |||
| AH 051210 | |||
| {{electro-stub}} | |||
| ] | |||
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