Design Considerations for the Mx-1 Controller
- Anand Rajaraman
- David Helbock
- Del Gonzalez
This section provides design and planning information about the Mx-1 one-door controller.
The Mx-1 controller is packaged in a compact lightweight plastic case, can be powered by either PoE+ (providing a nominal 25.5 Watts) or 24V - 28VDC power from an external power supply, and can be installed either “at the edge” (close to the door and readers) or stacked.
The Mx-1-ME controller is packaged in a traditional metal enclosure with a locking door, a tamper switch, a power supply, a standby battery pack, and room for optional expansion boards. Controllers with this type of enclosure are typically located in a safe and secure area, such as an electrical room, telephone equipment room, closet, or the security operations office. The back of the metal enclosure has holes for attaching it to the studs in a wall. (Because the Mx-1-ME model includes a power supply, its Ethernet connection does not include the Power over Ethernet functionality which is included on the standard Mx-1 model.)
An environmentally managed room is not required, because the Mx-1 controller can be operated in ambient temperatures of 0 degrees Centigrade (32 degrees Fahrenheit) to 60 degrees Centigrade (140 degrees Fahrenheit), with a maximum relative humidity of 90% (non-condensing).
In addition to monitoring, reporting, and controlling a variety of devices, an Mx-1 controller can typically power the attached entry reader and optional exit reader. Other devices, such as interior motion sensors and certain types of readers, may require power from a separate power supply.
If you are designing a security system that must meet certain standards (such as UL 294), see “UL Requirements”.
Electrical Ratings
An Mx-1 or Mx-1-ME controller has the following electrical ratings:
Table 3-9: Electrical Ratings of the Mx-1 or Mx-1-ME Controller’s Components
Component | Specifications |
|---|---|
Power Supply for the Mx-1 | Either a UL-listed PoE+ switch providing a nominal 25.5 Watts, or a UL-listed 2.0 A switching power supply at 110 - 240VAC and 50/60 Hz providing 24V - 28VDC power. |
Power Supply for the Mx-1-ME | The Mx-1-ME controller includes a switching AC power supply (with 2.0 A at 110 - 240VAC and 50/60 Hz), and two 12VDC standby batteries connected in series to provide 7.2 Ah at 24VDC. (Because the Mx-1-ME model includes a power supply, its Ethernet connection does not include the Power over Ethernet functionality which is included on the standard Mx-1 model.) |
Wiegand reader terminals | Two 8-pin Wiegand reader terminals, fused and resettable, each providing 12VDC power. Dedicated terminals are provided for the entry reader and the optional exit reader. On the Mx-1, these terminals provide up to 0.5 Amps each; on the Mx-1-ME, these terminals provide up to 0.355 Amps each. The maximum simultaneous current draw for the Wiegand Entry Reader terminal and the Wiegand Exit Reader terminal is 0.75 Amps. |
OSDP RS-485 readers terminal | One 5-pin OSDP RS-485 readers terminal, fused and resettable, providing 0.75 Amps at 12VDC. (When an optional exit reader is needed, it is wired “through” the entry reader.) |
Input sensor terminals | Two 3-pin input sensor terminals, used for an analog input such as the multistate alarm inputs provided by the line module that detects changes in the status of a door’s components (for example the position of the door contacts and the press of a Request to Exit button or the triggering of a motion detector). For more information, see “Line Modules” and “Connecting Line Module Inputs”. |
Door relay and Aux. relay terminals | Two 3-pin output relay terminals, one for the door, and one for the alarm or auxiliary devices. (For more information, see “Connecting Outputs”).
UL has only evaluated this relay for 30VDC at 2 Amps for resistive and inductive loads. Auxiliary Relay
UL has only evaluated this relay for 30VDC at 2 Amps for resistive and inductive loads. |
Total Power available for Readers and Relays in wet mode | The output power that is available for peripheral devices depends on the input power that is supplied to the Mx-1 controller:
For more information, see “Mx-1 Controller Power Draw Capacity”. |
Mx-1 Controller Design
The Mx-1 controller manages a single supervised door with an entry reader and an optional exit reader. The readers are connected either using the two Wiegand reader terminals, or using the OSDP RS-485 readers terminals. (When an exit reader is used with the Open Supervised Device Protocol (OSDP), it is wired “through” the entry reader, as shown in “Wiring Diagram for OSDP Readers”.)
Two input terminals are used for connecting analog inputs such as the multi-state alarm inputs provided by the line module that detects changes in the status of a door's components (for example the position of the door contacts and the press of a Request to Exit button or the triggering of a motion detector); a door relay terminal is used to control the door's locking mechanism (such as a magnetic lock or an electric strike); and an alarm relay terminal is used to control external alarm devices (such as activating an audible alarm, turning on lights, or initiating the recording of surveillance video).
An Mx-1 controller has built-in SNIB3 capability, so it includes an integrated Ethernet port for easy connection to the Velocity Server and an RS-485 Chaining terminal for connection to other controllers on a SCRAMBLE*NET network. The functionality of the Command and Control Module (CCMx) is also built into the mainboard (unlike previous controllers where the CCM or CCMx was on a separate replaceable module).
The Mx-1-ME model also supports certain optional expansion boards, as discussed in “Expansion Boards for an Mx-1-ME Controller”. The dimensions of the Mx-1-ME controller’s metal enclosure and the Mx-1 controller’s plastic case appear near the end of Table 1-1 in the section “Mx Series Controller Models”.
Supplying Power to an Mx-1 Controller
The Mx-1 controller can be powered either through its PoE+ Ethernet connector, or through its 2-pin Power terminal. When using PoE+, it should be sufficient to power the controller and the readers, but you might need to provide an external power supply for the door’s locking mechanism.
For the Mx-1-ME model, the 2-pin Power connector is wired to the included power supply (a UL-listed 2.0 A switching power supply at 110 - 240VAC and 50/60 Hz providing 30VDC power) at the factory. Because the Mx-1-ME model includes a power supply, its Ethernet connection does not include the Power over Ethernet (PoE) functionality which is included on the standard Mx-1 model.
When using AC power, follow these guidelines:
Locate the controller near a dedicated AC power source. A 15 Amp dedicated, unswitched circuit is required.
If the power in the building is correctly grounded, there is no special grounding required for the controller.
The entry point for the primary AC power is through the bottom or back of the enclosure. Connect AC power under the protective cover onto the supplied terminal strip, as shown in Figure 3-4, “Cable Inlets of the Mx-1-ME Controller’s Enclosure” in section “Separation of Circuits”.
Separation of Circuits
The Class 1 high-voltage AC input power for an Mx-1-ME controller is routed through either one of the two knockouts at the bottom of the enclosure, while the cables for the controller’s Class 2 circuits (such as inputs, Wiegand reader terminals, and OSDP reader terminals) are routed through several knock-outs located across the top and sides of the enclosure. This technique is shown in the following figure.
Figure 3-4: Cable Inlets of the Mx-1-ME Controller’s Enclosure
The Mx-1-ME controller’s Class 2 limited-power circuits include the following connections (as shown in Figure 3-2, in section “Mx-1 Controller Main Board”):
Two 3-wire analog Door Input and Aux. Input terminal blocks (for the line modules used to supervise doors, tamper circuits, and RQE devices).
Two 8-wire terminal blocks (for connecting the wiring from a 12VDC keypad or reader with a Wiegand interface). These are designed to support a variety of 125 kHz and 13.56 MHz readers and credentials.
One 5-wire terminal block (for connecting the wiring from a 12VDC keypad or reader with an OSDP RS-485 interface).
One Expansion Board Connector (which is used to link any expansion boards mounted in the controller’s enclosure to the controller’s main board, using a flexible EBIC5 ribbon cable).
One 6-pin RS-485 Controller Bus connector which can be used to create a chain of controllers, where the first (master) controller communicates directly with the Velocity Server using the PoE+ Ethernet connector, and the other (downstream) controllers communicate along the chain using RS-485 wiring. Otherwise, an Mx-1 controller can communicate directly with the Velocity Server across a network using the PoE+ Ethernet connector.
All reader circuits are protected by resettable thermal fuses, which automatically restore circuit integrity after the overcurrent has been removed. When routing the wires for the Class 2 limited-power circuits, make sure that you maintain a safe separation of at least 0.25 inches from the wires for the standby battery pack.
A complete list of the Mx-1-ME controller’s Class 2 limited-power connects is available in “Class 2 Limited-Power Connectors on an Mx-1-ME Controller”.
Mx-1-ME Controller Standby Battery Capacity
The Mx-1-ME controller comes factory-equipped with a 24V 1.3Ah battery pack, which consists of two 12-volt batteries connected in series for a full 24V standby unit. (These sealed lead-acid batteries should not be fully depleted.)
If still more backup power is required, the provided internal standby battery can be replaced by larger-capacity external 24VDC batteries (up to a limit of 14 amp-hours), or by a charger and batteries (such as those made by AlarmSafe). A 120/240VAC UPS can also be tied into the main power, providing the controller with both surge protection and emergency power. (UL has not tested these configurations.)
When using external batteries or a charger and batteries, remember:
When using an external battery pack, remove the controller’s internal battery and connect the new power line into the unused standby battery input on the controller board. Remember: connecting two similar batteries in series doubles the voltage.
When using a UPS, connect the UPS into the AC power line.
Use this formula to determine how much backup battery power a controller requires:
( IDevices + IController ) x hours = Battery Life Required
This is the sum of the load at 24VDC of all the attached devices plus the load at 24VDC of the controller itself, multiplied by the hours of battery operation required.
The next table provides the extended standby battery requirements (current draw in Amps) for the Mx-1-ME controller and several different Identiv TouchSecure readers, based on quiescent (idle) conditions.
Table 3-10: Quiescent Current Draw for the Mx-1-ME Controller and Various TouchSecure Readers
Controller or Attached Device | Current Draw @ 24VDC | Remarks |
|---|---|---|
Mx-1-ME controller | 0.45 A | Normal operating current. |
TouchSecure Standard reader | 0.075 A |
These readers are rated at 12V. |
TouchSecure ScramblePad reader (non-illuminated) | 0.09 A | |
TouchSecure Keypad reader | 0.14 A | |
Normally Closed Relay (in Wet mode) | 0.25 A | Assumes the Relay is always ON. |
For example, suppose an Mx-ME controller is connected to a door with a TouchSecure ScramblePad reader and a relay in Wet mode which is Normally Closed.
The installed example system’s current draw is itemized:
A factory-installed 7.2 Ah battery pack could support this configuration for:
However, if you specify that the extended standby battery backup requirement must be at least 24 hours of operation without primary power, then:
0.79 A x 24 hours = 18.96 Amp-hours
Obviously the included 1.3 Ah battery pack is not sufficient for this extended requirement. To operate this system without primary power for a full 24 hours, you will need to provide either an external battery or a front-end UPS, with the necessary capacity.
Here is another example for an Mx-ME controller which connected to a TouchSecure ScramblePad reader (enabling two-factor authentication for entry) and a TouchSecure Standard reader (for card-only exit). This example system’s current draw is:
The factory-installed 7.2 Ah battery pack could support this configuration for:
Power Provided at the Mx-1 Controller’s Reader Terminals
An Mx-1 or Mx-1-ME controller provides 12VDC power at its two Wiegand reader terminals, and 12VDC power at its RS-485 OSDP readers terminal. (For the Open Supervised Device Protocol (OSDP), when an optional exit reader is needed, it is wired “through” the entry reader.)
The following table shows the power provided for Wiegand and RS-485 OSDP keypads/readers by an Mx-1 or Mx-1-ME controller.
Table 3-11: Maximum Current Draws for an Mx-1 or Mx-1-ME Controller’s Reader Terminals
Reader Terminal Type | Max. Current Draw per Terminal | Max. Simultaneous Current Draw per Controller |
|---|---|---|
Wiegand | Mx-1: 0.5 A | 0.75 A |
RS-485 OSDP | 0.75 A | 0.75 A |
Mx-1 Controller Power Draw Capacity
When planning to use Mx-1 controllers as part of your physical access security system, you must consider how to supply adequate power for each controller, its entry reader and optional exit reader, the door’s access device (such as a magnetic lock or an electric strike), and any related optional devices for activating an audible alarm, turning on lights, or initiating the recording of surveillance video. This topic provides nformation about the power used by the Mx-1 controller and some Identiv TS readers, to help you determine whether you need to supply separate power for some of your peripheral devices.
The following table shows the current and power used by the Mx-1 controller, TS Scramblepad readers, and standard TS readers, when the controller’s input power is either DC or PoE+, so you can determine whether there is sufficient power available for the door’s access device (or whether you will have to provide separate power for that device).
Table 3-12: Maximum Current Draws for an Mx-1 Controller’s Reader Terminals
Parameter | 24V - 28VDC Input | PoE+ Input | Notes | ||
|---|---|---|---|---|---|
Current | Power | Current | Power | ||
Starting input current and power | 2.0 A | 48 Watts | 0.5 A | 24 Watts | Either PoE+, or an external power supply providing 24V - 28VDC with a max of 2 Amps. |
Mx-1 controller in standby state | 0.45 A | 10.8 Watts | 0.23 A | 11.04 Watts | Power consumed by the Mx-1 controller alone (without any attached readers, and no relays in Wet mode). |
Power available for all peripheral devices | See the Notes | 37.2 Watts | See the Notes | 12.96 Watts | Peripheral devices include the attached readers and relays in Wet mode (for devices powered by the Mx-1). The current varies depending on which device is drawing power. |
Power used by 2 TS Scramblepad readers (at 4.5 Watts each) | 375 mA each (at 12V out) | 9 Watts | 375 mA each (at 12V out) | 9 Watts | TS Scramblepad readers attached to the Wiegand Entry Reader terminal and the Wiegand Exit Reader terminal. |
Power available for relays when using 2 TS Scramblepad readers | — | 28.2 Watts | — | 3.96 Watts | TS Scramblepad readers attached to the Wiegand Entry Reader terminal and the Wiegand Exit Reader terminal. |
Power used by 2 standard TS readers (at 1.5 Watts each) | 125 mA each (at 12V out) | 3 Watts | 125 mA each (at 12V out) | 3 Watts | Standard TS readers attached to the Wiegand Entry Reader terminal and the Wiegand Exit Reader terminal. |
Power available for relays when using 2 standard TS readers | — | 34.2 Watts | — | 9.96 Watts | Standard TS readers attached to the Wiegand Entry Reader terminal |
The following table shows the current provided by the Mx-1 controller to its Door relay and Aux. relay, when the controller’s input power is either 24VDC or PoE+, so you can determine whether there is sufficient current available for the devices controlled by those relays (or whether you will have to provide separate power for those devices), and you can determine the correct power mode jumper setting (either Wet at 24V, Wet at 12V, or Dry) for those relays.
Table 3-13: Current Provided for an Mx-1 Controller’s Door Relay and Aux. Relay
Parameter | Current with 24VDC Input | Current with PoE+ Input | Notes |
|---|---|---|---|
Door relay in Wet Mode at 24V | 750 mA (at 24V) | 750 mA (at 24V) | The door’s access device (such as a magnetic lock or an electric strike) is powered by the Mx-1. |
Door relay in Wet Mode at 12V | 750 mA (at 12V) | 750 mA (at 12V) | The door’s access device (such as a magnetic lock or an electric strike) is powered by the Mx-1. |
Door relay in Dry Mode | Up to 2.0 A (at 30V) | Up to 2.0 A (at 30V) | The door’s access device (such as a magnetic lock or an electric strike) is externally powered. |
Aux. relay in Wet Mode at 24V | 750 mA (at 24V) | 750 mA (at 24V) | The external alarm or auxiliary device is powered by the Mx-1. |
Aux. relay in Wet Mode at 12V | 750 mA (at 12V) | 750 mA (at 12V) | The external alarm or auxiliary device is powered by the Mx-1. |
Aux. relay in Dry Mode | Up to 2.0 A (at 30V) | Up to 2.0 A (at 30V) | The external alarm or auxiliary device is externally powered. |