ALTA Long Range Wireless Button Press Sensor Manuale utente

Marca: ALTA

Modello: Long Range Wireless Button Press Sensor

Tipo: Manuale utente

Remote Monitoring for Business

Wireless Button Press Sensor

USER GUIDE

Table of Contents

PAGE II

I. ABOUT THE WIRELESS BUTTON PRESS SENSOR 1

ALTA WIRELESS BUTTON PRESS FEATURES 1

EXAMPLE APPLICATIONS 1

II. ORDER OF OPERATIONS 2

III. SETUP AND INSTALLATION 3

IV. SETTING UP YOUR BUTTON PRESS SENSOR 5

INSTALLING BATTERIES 5

ANTENNA ORIENTATION 6

V. SENSOR OVERVIEW IN iMONNIT 7

MENU SYSTEM 7

VI. ACTIONS OVERVIEW 10

CREATING AN ACTION 10

VII. SECURITY 14

SENSOR TO GATEWAY 14

GATEWAYTO iMONNIT 14

iMONNIT 14

SENSOR PRINTS 14

SUPPORT 15

WARRANTY INFORMATION 15

CERTIFICATIONS 17

SAFETY RECOMMENDATIONS 19

I. ABOUT THE WIRELESS BUTTON PRESS SENSOR

PAGE 1

ALTA WIRELESS BUTTON PRESS FEATURES

- Wireless range of 1,200+ feet through 12+ walls *

- Frequency-Hopping Spread Spectrum (FHSS)

- Interference immunity

- Power management for longer battery life **

- Encrypt-RF® Security (Diffie-Hellman Key Exchange + AES-128 CBC for sensor data

messages)

- Onboard data memory stores up to hundreds of readings per sensor:

- 10-minute heartbeats = 3.5 days

- 2-hour heartbeats = 42 days

- Over-the-air updates (future proof)

- Free iMonnit basic online wireless sensor monitoring and notification system to

configure sensors, view data and set alerts via SMS text and email

* Actual range may vary depending on environment.

** Battery life is determined by sensor reporting frequency and other variables. Other power options are also

available.

EXAMPLE APPLICATIONS

- Hotel/motel front desk call button

- Restroom service/clean-up request button

- Service request button

- Additional applications.

The ALTA Wireless Button Sensor sends a signal to the iMonnit Online Sensor Monitoring

and Notification System when the button is pressed triggering a notification via SMS text or

email and tracking the data in the online system and can be reviewed and exported as a

data sheet or graph. Notifications can be set up through the online system to alert the user

immediately when movement is detected with the ability to only notify within time of day

parameters.

The ALTA Wireless Button Sensor detects when the button has been pressed triggering a

notification from the system.

PAGE 2

II. ORDER OF OPERATIONS

It is important to understand the order of operations for activating your sensor. If performed

out of sequence, your sensor may have trouble communicating with iMonnit. Please

perform the steps below in the order indicated to make sure you are performing your set-up

correctly.

1. Create iMonnit Account (If new user).

2. Register all sensors and gateways to a network in iMonnit.

Sensors can only communicate with gateways on the same iMonnit

network.

3. Connect/power on gateway and wait till it checks into iMonnit.

4. Power on sensor and verify it checks into iMonnit.

We recommend powering the sensor on near the gateway then moving to the

installation location, checking signal strength along the way.

5. Configure sensor for use (This can be done at any point after step 2)

6. Install sensor in final location.

Note: Device specific setup is covered in more detail in the following

sections.

Note: For information on setting up iMonnit and the gateway refer to

the iMonnit User Guide and the gateways user guide.

PAGE 3

III. SETUP AND INSTALLATION

If this is your first time using the iMonnit online portal, you will need to create a new

account. If you have already created an account, start by logging in. For instructions on how

to register and setup your iMonnit account, please consult the iMonnit User Guide.

STEP 1: ADD DEVICE

1. Add the sensor on iMonnit.

Add the sensor to your account by choosing Sensors in the main menu.

Navigate to the Add Sensor button.

2. Find the device ID. See Figure 1.

The Device ID (ID) and Security Code

(SC) are necessary to add a sensor.

These can both be located on the label

on the side of your device.

3. Adding your device. See Figure 2.

You will need to enter the Device ID

and the Security Code from your

Sensor in the corresponding text boxes.

Use the camera on your smartphone to

scan the QR code on your device. If you

do not have a camera on your phone,

or the system is not accepting the QR

code, you may enter the Device ID

and Security Code manually.

- The Device ID is a unique number

located on each device label.

- Next, you?ll be asked to enter the Security Code from your device. A

security code consists of letters and must be entered in upper case (no

numbers). It can also be found on the barcode label of your device.

When completed, select the Add Device button.

Figure 1

Figure 2

Desktop Mobile

Select your use case. See Figure 3.

Unlike most sensors, choosing a use case in

Step 2 of adding this sensor does not give

you the option to customize your settings.

These will need to be adjusted in the

settings tab for your device. See page 9 for

instructions.

Select the Skip button when completed.

STEP 2: SETUP

Figure 3

Check your signal. See Figure 4.

The validation checklist will help you ensure your

sensor is communicating with the gateway properly

and you have a strong signal.

Checkpoint 4 will only complete when your sensor

achieves a solid connection to the gateway. Once

you insert the batteries (or flip the switch on an

industrial sensor) the sensor will communicate with

the gateway every 30 seconds for the first few

minutes.

Select the Save button when completed.

STEP 3: VALIDATION

Figure 4

STEP 4: ACTIONS

Choose your actions. See Figure 5.

Actions are the alerts that will be sent to your phone

or email in the event of an emergency. Low battery

life and device inactivity are two of the most

common actions to have enabled on your device.

See page 12 for how to set actions for your sensor.

Select the Done button when completed.

Figure 5

PAGE 4

IV. SETTING UP YOUR BUTTON PRESS SENSOR

When you are finished adding the sensor to your account, the next step is to insert the

battery. The type of battery you use will depend on the category of your sensor. ALTA

Wireless Button Press Sensors will either be powered by commercial coin cell or a set of

two AA batteries.

PAGE 5

INSTALLING BATTERIES

ALTA commercial sensors are powered by AA or CR2032 coin cell batteries. Monnit

encourages customers to recycle all old batteries.

Coin Cell

The lifespan of a standard CR2032 coin cell

battery in an ALTA Button Press Sensor is up to 2

years.

Install a coin cell battery by first taking the sensor

and pinching the sides of the enclosure. Gently pull

up the enclosure, separating the sensor from its

base. Then slide a new CR2032 coin cell battery

with the positive side facing toward the base. Press

the enclosure back to together; you?ll hear a small

click.

Lastly, open iMonnit select Sensors from the navigation menu. Verify that iMonnit is

showing the sensor has a full battery level.

AA Batteries

The standard version of this sensor is powered by

two replaceable 1.5 V AA sized batteries (included

with purchase). The typical battery life is up to 10

years.

This sensor is also available with a line power option.

The line powered version of this sensor has a barrel

power connector allowing it to be powered by a

standard 3.0?3.6 V power supply. The line powered

version also uses two standard 1.5 V AA batteries as

backup for uninterrupted operation in the event of line

power outage.

Power options must be selected at time of purchase,

as the internal hardware of the sensor must be

changed to support the selected power requirements.

Place batteries in the device by first taking the sensor and sliding the battery door open.

Insert fresh AA batteries in the carriage, then shut the battery door.

Complete the process by opening up iMonnit and selecting Sensors from the main

navigation menu. Verify that iMonnit is showing the sensor has a full battery level.

Figure 6

Figure 7

Figure 8

ANTENNA ORIENTATION

More Signal

Less Signal

PAGE 6

In order to get the best performance out of your ALTA Wireless Sensors, it is important to

note proper antenna orientation and sensor positioning. Antennas should all be oriented in

the same direction, pointing vertically from the sensor. If the sensor is mounted flat on its

back on a horizontal surface, you should bend the antenna as close to the sensor housing

as possible giving you the most amount of antenna pointing vertical. You should make the

antenna wire as straight as possible, avoiding any kinks and curving of the wire. Sensors

must be at least 3 ft. away from other sensors and the wireless gateway to function.

Figure 9

Figure 10

PAGE 7

V. SENSOR OVERVIEW IN iMONNIT

Select Sensors from the main navigation menu on iMonnit to access the sensor overview

page and begin making adjustments to your Button Press Sensor .

MENU SYSTEM

A. Details - Displays a graph of recent sensor data

B. History - List of all past heartbeats and readings

C. Events - List of all events attached to this sensor

D. Settings - Editable levels for your sensor

Directly under the tab bar is an overview of your sensor. This allows you to see the signal

strength and the battery level of the selected sensor. A colored dot in the left corner of the

sensor icon denotes its status.

Details View

The Details View will be the first page you see upon selecting which sensor you would like

to modify.

A. The sensor overview section will be

above every page. This will consistently

display the present reading, signal strength,

battery level, and status.

B. The Recent Readings section below the

chart shows your most recent data received

by the sensor.

C. This graph charts how the sensor

fluctuates throughout a set date range. To

change the date range displayed in the

graph, navigate up to the top of the

Readings Chart section on the right-hand

corner to change the from and/or to date.

- Green indicates the sensor is checking in and within user-defined safe

parameters.

- Red indicates the sensor has met or exceeded a user-defined thereshold or

triggered event.

- Gray indicates that no sensor readings are being recorded, rendering the sensor

inactive.

- Yellow indicates that the sensor reading is out of date, due to perhaps a missed

heartbeat check-in.

A B C D

Figure 11

Figure 12

PAGE 8

Readings View

Selecting the Readings Tab within the tab bar allows you to view the sensor?s

data history as time stamped data.

- On the far right of the Sensor History Data is a cloud icon. ( ) Selecting this icon

will export an Excel file for your sensor into your download folder.

The data file will have the following fields:

MessageID: Unique identifier of the message in our database.

Sensor ID: If multiple sensors are exported, you can distinguish between the

sensors using this number ? even if the names are the same.

Sensor Name: The name you have given the sensor.

Date: The date the message was transmitted from the sensor.

Value: Data presented with transformations applied, but without additional

labels.

Formatted Value: Data transformed and presented as it is shown in the

monitoring portal.

Raw Data: Raw data as it is stored from the sensor.

Sensor State: Binary field represented as an integer containing information

about the state of the sensor when the message was transmitted. (See

?Sensor State? explained below.)

Alert Sent: Boolean indicating if this reading triggered a notification to be sent

from the system.

Sensor State

The value presented here is generated from a single byte of stored data.

A byte consists of 8 bits of data that we read as Boolean (True (1) / False (0))

fields.

When broken into individual bits, the State byte contains the following information:

aaaabcde

STS: This value is specific to the sensor profile and is often used to indicate error states

and other sensor conditions.

UNUSED: This sensor does not use these bits.

AWARE: Sensors become aware when critical sensor specific conditions are met. Going

aware can cause the sensor to trigger and report before the heartbeat and cause the

gateway to forward the data to the server immediately resulting in near immediate

transmission of the data.

TEST: This bit is active when the sensor is first powered on or reset and remains active

for the first 9 messages when using default configurations.

STS Specific Codes:

0 = No problems, sensor is functioning normally.

1 = Open circuit detected in lead.

2 = Short circuit detected in lead.

3 = Range error. Temperature is reading outside of -40 F and 257 F (-40 C and 125 C).

Note: Make sure you have the date range for the data you need input

in the ?From? and ?To? text boxes. This will be the previous day by

default. Only the first 2,500 entries in the selected date range will be

exported.

PAGE 9

Settings View

To edit the operational settings for a sensor, choose the ?Sensor? option in the main

navigation menu then select the ?Settings? tab to access the configuration page.

The default heartbeat interval is 120 minutes or two hours. It is recommended that you do

not lower your heartbeat level too much because it will drain the battery.

A. Sensor Name is the unique name you give the sensor to easily identify it in a list and in

any notifications.

B. Heartbeat Interval is how often the sensor communicates with the gateway if no activity

is recorded.

C. Time to Re-Arm (seconds) is the time in seconds after a triggering event that the

sensor will wait before re-arming itself.

D. Failed transmissions before link mode is the number of transmissions the sensor

sends without response from a gateway before it goes to battery saving link mode. In link

mode, the sensor will scan for a new gateway and if not found will enter battery saving

sleep mode for up to 60 minutes before trying to scan again. Lower numbers will allow

sensors to find new gateways with fewer missed readings. Higher numbers will enable the

sensor to remain with its current gateway in a noisy RF environment better (Zero will cause

the sensor to never join another gateway to find a new gateway, the battery will have to be

cycled out of the sensor.)

Finish by selecting the Save button.

Note: Be sure to select the Save button anytime you make a change to any of

the sensor parameters. All changes made to the sensor settings will be

downloaded to the sensor on the next sensor heartbeat (check-in). Once a

change has been made and saved, you will not be able to edit that sensor?s

configuration again until it has downloaded the new setting.

Figure 13

PAGE 10

VI. ACTIONS OVERVIEW

Device notifications can be created, deleted, and edited by selecting the Actions Tab in the

tab bar.

You can toggle the Action Trigger on or off by selecting the switch under Current Action

Triggers. See Figure 14.

CREATING AN ACTION

- Actions are triggers or alarms set to notify you when a sensor reading identifies that

immediate attention is needed. Types of actions include sensor readings, device

inactivity, and scheduled data. Any one of these can be set to send a notification or

trigger an action in the system.

Choose Actions in the main navigation menu.

- A list of previously created actions will display on the screen. From here, you have

the ability to filter, refresh, and add new actions to the list.

Note: If this is your first time adding an action, the screen will be blank.

Figure 14

Figure 15

From the Actions page, tap Add Action in the left hand corner.

Step 1: What triggers your action?

The drop-down menu will have the following options for Action Types (See

Figure 17):

- Select Sensor Reading from the drop-down menu.

- A second drop-down menu will appear. From here, you will be able to see

a list of the different type of sensors registered to your account. Choose

Button in the drop-down menu.

- Next, you will be asked to input the trigger settings. You have the

option of setting this trigger to detect whether a button has been Pressed

or Not Pressed.

Press the Save button.

- Sensor Reading: Set actions based

on activity or reading.

- Device Inactivity: Actions when the

device doesn?t communicate for an

extended period of time.

- Advanced: Actions based on

advanced rules, such as comparing

past data points with current ones.

- Scheduled: These actions are

performed at a time set basis.

Figure 16

Figure 17

Figure 18

PAGE 11

Step 2: Actions

- Press the Add Action button under the information header, available

action types will then be presented in a select list.

- Notification Action: Specify account users to receive notification when

this event triggers.

- System Action: Assign actions for the system to process when this

event triggers.

- Choose Notification Action from the notification list.

A. Input the subject for the notification.

See Figure 19.

B. Customize the message body

for the notification. See Figure 19.

C. Recipient list identifies who will

receive the notification.

See Figure 20.

- Select the icon next to a user to specify how they will be notified.

- Choose if you want notifications sent immediately, when triggered, or if

you want a delay before sending and press Set.

- A green icon indicates that the users that will receive the notifications.

- If a delay has been selected, the delay time will display beside the icon.

Figure 19

Figure 20

PAGE 12

Select System Action from the Add Action list. See Figure 21.

Acknowledge: Automatically signals

that you have been notified of an action.

When an action has been triggered,

alerts will continue processing until the

action returns to a value that no longer

triggers an action.

Full Reset: Reset your trigger so it is

armed for the next reading.

Activate: Enable an action trigger.

Deactivate: Disable an action trigger.

Figure 21

Figure 22

- Scroll down to the System Action

section.

- The Action to be done select list has

the following options:

Step 3: Action Name and Devices

- By default, the sensor(s) will not be

assigned to the action conditions

you?ve just set. To assign a sensor,

find the device(s) you want to

designate for this action and select.

Selected sensor boxes will turn green

when activated. Choose the sensor

box again to unassign the sensor

from the action. See Figure 22.

- Continue toggling the sensor(s)

corresponding to this new action until

you are satisfied with your selection.

These can be adjusted later by

returning to this page.

Press the Check-mark button to complete the process.

PAGE 13

VII. SECURITY

Data security and integrity is paramount at Monnit. Each layer of the system is secured

using encryption and protocols designed to protect customer data and information. The

system consists of sensor(s), gateway(s), and iMonnit software. One or more sensors

communicate with iMonnit software through a gateway.

SENSOR TO GATEWAY

Sensor and gateway radio modules are purpose built devices with proprietary unreadable

firmware, which means the sensor cannot be physically hacked or re-purposed for

malicious purposes. This adds a strong level of inherent security even before considering

encryption. Data transmission between the sensor and gateway are secured using

Encrypt-RF Security (Diffie-Hellman Key Exchange + AES-128 CBC for sensor data

messages). Beyond the encryption, data transmissions are also structurally verified and

CRC checked before they are passed up to iMonnit or down to the sensor, this ensures the

integrity of the data itself.

GATEWAY TO IMONNIT

Data transmissions between the gateway and iMonnit software are secured using 256-bit,

bank level encryption.

iMONNIT

Access is granted through the iMonnit user interface, or an Application

Programming Interface (API) safeguarded by 256-bit Transport Layer Security (TLS 1.2)

encryption. TLS is a blanket of protection to encrypt all data exchanged between iMonnit

and you. The same encryption is available to you whether you are a Basic or Premiere user

of iMonnit. You can rest assured that your data is safe with iMonnit.

SENSOR PRINTS

Sensor prints utilize a shared key between the software and the sensor to ensure that once

the data comes to iMonnit it is guaranteed to be from the device identified by the sensor

print. If this feature is purchased for the device (via iMonnit software) the devices data

becomes impossible to spoof by any malicious device.

PAGE 14

PAGE 15

SUPPORT

For technical support and troubleshooting tips please visit our support library online at

monnit.com/support/. If you are unable to solve your issue using our online support, email

Monnit support at [email protected] with your contact information and a description of

the problem, and a support representative will call you within one business day.

For error reporting, please email a full description of the error to [email protected].

WARRANTY INFORMATION

(a) Monnit warrants that Monnit-branded products (Products) will be free from defects in

materials and workmanship for a period of one (1) year from the date of delivery with

respect to hardware and will materially conform to their published specifications for a period

of one (1) year with respect to software. Monnit may resell sensors manufactured by other

entities and are subject to their individual warranties; Monnit will not enhance or extend

those warranties. Monnit does not warrant that the software or any portion thereof is error

free. Monnit will have no warranty obligation with respect to Products subjected to abuse,

misuse, negligence or accident. If any software or firmware incorporated in any Product

fails to conform to the warranty set forth in this Section, Monnit shall provide a bug fix or

software patch correcting such non-conformance within a reasonable period after Monnit

receives from Customer (i) notice of such non-conformance, and (ii) sufficient information

regarding such non-conformance so as to permit Monnit to create such bug fix or software

patch. If any hardware component of any Product fails to conform to the warranty in this

Section, Monnit shall, at its option, refund the purchase price less any discounts, or repair

or replace nonconforming Products with conforming Products or Products having

substantially identical form, fit, and function and deliver the repaired or replacement

Product to a carrier for land shipment to customer within a reasonable period after Monnit

receives from Customer (i) notice of such non-conformance, and (ii) the non-conforming

Product provided; however, if, in its opinion, Monnit cannot repair or replace on

commercially reasonable terms it may choose to refund the purchase price. Repair parts

and replacement Products may be reconditioned or new. All replacement Products and

parts become the property of Monnit. Repaired or replacement Products shall be subject to

the warranty, if any remains, originally applicable to the product repaired or replaced.

Customer must obtain from Monnit a Return Material Authorization Number (RMA) prior to

returning any Products to Monnit. Products returned under this Warranty must be

unmodified.

Customer may return all Products for repair or replacement due to defects in original

materials and workmanship if Monnit is notified within one year of customer?s receipt of the

product. Monnit reserves the right to repair or replace Products at its own and complete

discretion. Customer must obtain from Monnit a Return Material Authorization Number

(RMA) prior to returning any Products to Monnit. Products returned under this Warranty

must be unmodified and in original packaging. Monnit reserves the right to refuse warranty

repairs or replacements for any Products that are damaged or not in original form. For

Products outside the one year warranty period repair services are available at Monnit at

standard labor rates for a period of one year from the Customer?s original date of receipt.

(b) As a condition to Monnit?s obligations under the immediately preceding paragraphs,

Customer shall return Products to be examined and replaced to Monnit?s facilities, in

shipping cartons which clearly display a valid RMA number provided by Monnit. Customer

acknowledges that replacement Products may be repaired, refurbished or tested and found

to be complying. Customer shall bear the risk of loss for such return shipment and shall

bear all shipping costs. Monnit shall deliver replacements for Products determined by

Monnit to be properly returned, shall bear the risk of loss and such costs of shipment of

repaired Products or replacements, and shall credit Customer?s reasonable costs of

shipping such returned Products against future purchases.

PAGE 16

or replace non-conforming products as set forth in the immediately preceding paragraph, or

to refund the documented purchase price for non-conforming Products to Customer.

Monnit?s warranty obligations shall run solely to Customer, and Monnit shall have no

obligation to customers of Customer or other users of the Products.

Limitation of Warranty and Remedies.

THE WARRANTY SET FORTH HEREIN IS THE ONLY WARRANTY APPLICABLE TO

PRODUCTS PURCHASED BY CUSTOMER. ALL OTHER WARRANTIES, EXPRESS OR

IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF

MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE EXPRESSLY

DISCLAIMED. MONNIT?S LIABILITY WHETHER IN CONTRACT, IN TORT, UNDER ANY

WARRANTY, IN NEGLIGENCE OR OTHERWISE SHALL NOT EXCEED THE PURCHASE

PRICE PAID BY CUSTOMER FOR THE PRODUCT. UNDER NO CIRCUMSTANCES

SHALL MONNIT BE LIABLE FOR SPECIAL, INDIRECT OR CONSEQUENTIAL

DAMAGES. THE PRICE STATED FOR THE PRODUCTS IS A CONSIDERATION IN

LIMITING MONNIT?S LIABILITY. NO ACTION, REGARDLESS OF FORM, ARISING OUT

OF THIS AGREEMENT MAY BE BROUGHT BY CUSTOMER MORE THAN ONE YEAR

AFTER THE CAUSE OF ACTION HAS ACCRUED.

IN ADDITION TO THE WARRANTIES DISCLAIMED ABOVE, MONNIT SPECIFICALLY

DISCLAIMS ANY AND ALL LIABILITY AND WARRANTIES, IMPLIED OR EXPRESSED,

FOR USES REQUIRING FAIL-SAFE PERFORMANCE IN WHICH FAILURE OF A

PRODUCT COULD LEAD TO DEATH, SERIOUS PERSONAL INJURY, OR SEVERE

PHYSICAL OR ENVIRONMENTAL DAMAGE SUCH AS, BUT NOT LIMITED TO, LIFE

SUPPORT OR MEDICAL DEVICES OR NUCLEAR APPLICATIONS. PRODUCTS ARE

NOT DESIGNED FOR AND SHOULD NOT BE USED IN ANY OF THESE

APPLICATIONS.

PAGE 17

CERTIFICATIONS

United States FCC

This equipment has been tested and found to comply with the limits for a Class B digital

devices, pursuant to Part 15 of the FCC Rules. These limits are designed to provide

reasonable protection against harmful interference in a residential installation. This

equipment generates, uses, and can radiate radio frequency energy and, if not installed

and used in accordance with the instruction manual, may cause harmful interference to

radio communications. However, there is no guarantee that interference will not occur in a

particular installation. If this equipment does cause harmful interference to radio or

television reception, which can be determined by turning the equipment off and on, the

user is encouraged to try to correct the interference by one of more of the following

measures:

- Reorient or relocate the receiving antenna.

- Increase the separation between the equipment and receiver

- Connect the equipment into an outlet on a circuit different from that to which the

receiver is connected.

- Consult the dealer or an experienced radio/TV technician for help.

Warning: Changes or modifications not expressly approved by Monnit could void

the user?s authority to operate the equipment.

RF Exposure

WARNING: To satisfy FCC RF exposure requirements for mobile

transmitting devices, the antenna used for this transmitter must not be

co-located in conjunction with any antenna or transmitter.

Monnit and ALTA Wireless Sensors:

This equipment complies with the radiation exposure limits prescribed for an uncontrolled

environment for fixed and mobile use conditions. This equipment should be installed and

operated with a minimum distance of 23 cm between the radiator and the body of the user

or nearby persons.

All ALTA Wireless Sensors Contain FCC ID: ZTL-G2SC1. Approved Antennas

ALTA devices have been designed to operate with an approved antenna listed below, and

having a maximum gain of 14 dBi. Antennas having a gain greater than 14 dBi are strictly

prohibited for use with this device. The required antenna impedance is 50 ohms.

- Xianzi XQZ-900E (5 dBi Dipole Omnidirectional)

- HyperLink HG908U-PRO (8 dBi Fiberglass Omnidirectional)

- HyperLink HG8909P (9 dBd Flat Panel Antenna)

- HyperLink HG914YE-NF (14 dBd Yagi)

- Specialized Manufacturing MC-ANT-20/4.0C (1 dBi 4? whip)

PAGE 18

Monnit Corporation

3400 South West Temple Salt Lake City, UT 84115 801-561-5555

www.monnit.com

Canada (IC)

English

Under Industry Canada regulations, this radio transmitter may only operate using an

antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry

Canada. To reduce potential radio interference to other users, the antenna type and its gain

should be so chosen that the Equivalent Isotropically Radiated Power (E.I.R.P.) is not more

than that necessary for successful communication.

The radio transmitters (IC: 9794A-RFSC1, IC: 9794A-G2SC1, IC: 4160a-CNN0301, IC:

5131A-CE910DUAL, IC: 5131A-HE910NA, IC: 5131A-GE910 and IC: 8595A2AGQN4NNN)

have been approved by Industry Canada to operate with the antenna types listed on

previous page with the maximum permissible gain and required antenna impedance for

each antenna type indicated. Antenna types not included in this list, having a gain greater

than the maximum gain indicated for that type, are strictly prohibited for use with this

device.

This device complies with Industry Canada license-exempt RSS standard(s). Operation is

subject to the following two conditions: (1) this device may not cause interference, and (2)

this device must accept any interference, including interference that may cause undesired

operation of the device.

French

Conformément à la réglementation d?Industrie Canada, le présent émetteur radio peut

fonctionner avec une antenne d?un type et d?un gain maximal (ou inférieur) approuvé pour

l?émetteur par Industrie Canada. Dans le but de réduire les risques de brouillage

radioélectrique à l?intention des autres utilisateurs, il faut choisir le type d?antenne et son

gain de sorte que la Puissance Isotrope Rayonnée Èquivalente (P.I.R.È) ne dépasse pas

l?intensité nécessaire à l?établissement d?une communication satisfaisante.

Le présent émetteurs radio (IC: 9794A-RFSC1, IC: 9794A-G2SC1, IC: 4160a-CNN0301,

IC: 5131A-CE910DUAL, IC: 5131A-HE910NA, IC: 5131A-GE910 et IC:

8595A2AGQN4NNN) a été approuvé par Industrie Canada pour fonctionner avec les types

d?antenne figurant sur la page précédente et ayant un gain admissible maximal et

l?impédance requise pour chaque type d?antenne. Les types d?antenne non inclus dans

cette liste, ou dont le gain est supérieur au gain maximal indiqué, sont strictement interdits

pour l?exploitation de l?émetteur.

Le présent appareil est conforme aux CNR d?Industrie Canada applicables aux appareils

radio exempts de licence. L?exploitation est autorisée aux deux conditions suivantes : (1)

l?appareil ne doit pas produire de brouillage, et (2) l?utilisateur de l?appareil doit accepter

tout brouillage radioélectrique subi, méme si le brouillage est susceptible d?en

compromettre le fonctionnement.

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ALTA Long Range Wireless Button Press Sensor Manuale utente

Marca: ALTA

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English: ALTA Long Range Wireless Button Press Sensor User manual

ALTA Long Range Wireless Button Press Sensor Manuale utente

ALTA Long Range Wireless Button Press Sensor Manuale utente

in altre lingue

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