Wireless Touch Panel with Intercom Reference Guide
Table Of Contents
- MVP-8400iModero® ViewPoint® Wireless Touch Panel with Intercom
- MVP-8400i Modero Viewpoint Wireless Touch Panel With Intercom
- MVP-BP Power Pack
- NXA-CFSP Compact Flash
- Wireless Interface Cards
- Configuring Communications
- Modero Setup and System Settings
- Wireless Settings Page - Wireless Access Overview
- Configuring a Wireless Network Access
- Step 1: Configure the Panel’s Wireless IP Settings
- Step 2: Configure the Card’s Wireless Security Settings
- Step 3: Choose a Master Connection Mode
- Using G4 Web Control to Interact with a G4 Panel
- Using your NetLinx Master to control the G4 panel
- Upgrading MVP Firmware
- Setup Pages
- Navigation Buttons
- Setup Pages
- Information
- Protected Setup Pages
- Protected Setup Navigation Buttons
- G4 Web Control Page
- Calibration Page
- Wireless Settings Page
- Wireless Security Page
- Open (Clear Text) Settings
- Static WEP Settings
- WPA-PSK Settings
- EAP-LEAP Settings
- EAP-FAST Settings
- EAP-PEAP Settings
- EAP-TTLS Settings
- EAP-TLS Settings
- Client certificate configuration
- System Settings Page
- Other Settings
- Tools
- Programming
- Panel Calibration
- Appendix A: Text Formatting
- Appendix B - Wireless Technology
- Appendix C: Troubleshooting
- Checking AMX USBLAN device connections via Windows Device Manager
- Checking AMX USBLAN device connections via NetLinx Studio
- USB Driver
- Panel Not in Listed As a Connected Device
- Connection Status
- Panel Doesn’t Respond To Touches
- Batteries Will Not Hold Or Take A Charge
- Modero Panel Isn’t Appearing In The Online Tree Tab
- MVP Can’t Obtain a DHCP Address
- My WEP Doesn’t Seem To Be Working
- NetLinx Studio Only Detects One Of My Connected Masters
- Can’t Connect To a NetLinx Master
- Only One Modero Panel In My System Shows Up
- Panel Behaves Strangely After Downloading A Panel File Or Firmware
- Panel Fails to Charge in MVP-WDS
Appendix B - Wireless Technology
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MVP-8400i Modero Viewpoint Wireless Touch Panels
Appendix B - Wireless Technology
Overview of Wireless Technology
802.11b/2.4 GHz and 802.11a/5 GHz are the two major WLAN standards and both operate
using radio frequency (RF) technology. Together the two standards are together called Wi-Fi
and operate in frequency bands of 2.4 GHz and 5 GHz respectively.
The 802.11b specification was the first to be finalized and reach the marketplace. The actual
throughput you can expect to obtain from an 802.11b network will typically be between 4 and
5 Mbps.
Because of the higher frequency (and thus shorter wavelength) that they use, 802.11a signals
have a much tougher time penetrating solid objects like walls, floors, and ceilings. As a result,
the price for 802.11a's higher speed is not only shorter in range but also a weaker and less
consistent signal.
802.11g provides increased bandwidth at 54 Mbps. As part of the IEEE 802.11g specification,
when throughput cannot be maintained, this card will automatically switch algorithms in
order to maintain the highest spread possible at a given distance. In addition, 802.11g can also
step down to utilize 802.11b algorithms and also maintain a connection at longer distances.
IP Routing is a behavior of the wireless routing is largely dependent on the wired network
interface. Although the panel can be connected to two networks simultaneously it may only
have one gateway. If the wired network was successfully set up and a gateway was obtained;
then the default route for all network traffic will be via the wired network. In the event that the
wired network was not configured, then the default route for all network traffic will be via the
wireless network. The wired network connection always takes priority.
As an example: Imagine a panel connected to two networks A & B. A is the wired
network and B is the wireless network. If the Master controller is on either of these
networks then it will be reached. However if the Master controller is on a different
network, C, then determining which network interface (wired or wireless) that will
be used is dependent on the gateway.
Wireless Access Points are the cornerstone of any wireless network. A Wireless Access Point
acts as a bridge between a wired and wireless network. It aggregates the traffic from all the
wireless clients and forwards it down the network to the switch or router.
One Wireless Access Point may be all you need. However, you could need more Wireless
Access Points depending on either how large your installation is, how it is laid out, and how it
is constructed.
Wireless Equivalent Privacy (WEP) Security is a method by which WLANs protect wireless
data streams. A data stream encrypted with WEP can still be intercepted or eavesdropped
upon, but the encryption makes the data unintelligible to the interloper. The strength of WEP
is measured by the length of the key used to encrypt the data. The longer the key, the harder it
is to crack.
802.11b implementations provided 64-bit and 128-bit WEP keys. This is known respectively
as 64-bit and 128-bit WEP encryption. 64-bit is generally not regarded as adequate security
protection. Both key lengths are supported by the Modero product line.
Whichever level of WEP you use, it's crucial to use identical settings (CASE SENSITIVE)--
the key length, and the key itself-- on all devices. Only devices with common WEP settings
will be able to communicate. Similarly, if one device has WEP enabled and another doesn't,
they won't be able to talk to each other.