IP65 IP Mesh Radio Command Suitcase
Police IP MESH Radio Command Station MANET AES Encryption IP65
Introduction
The MANET2501 is a portable wireless IP MESH command station, which is designed for on-site command. It can be used to manage settings of each MESH node, view the signal strength of each link, view video & data information, and conduct voice communication (Push-to-Talk). With built-in battery and also support external AC power input. It can be used as a frontline command post, as well as transmitting data back to the general command center through the 4G private and public networks to coordinate operations. It comes in a rugged shockproof, waterproof and dustproof pelican suitcase.
Features
■ Integrated IPC for easy operation
■ Infrastructure-less, self configuring and self healing
■ Supports 1400-1480MHz (350MHz-4GHz customizable)
■ Data rate up to 80Mbps
■ Range up to 1-2km NLOS
■ Supports up to 9 hops and no less than 50 nodes
■ Full transparent IP data transmission
■ Supports two-way intercom
■ HDMI output as optional
■ Supports 2.4G/5.8G WIFI and 4G connection
■ Supports AES256 encryption
■ Battery endurance up to 4-5 hours
■ Rugged IP65 housing
■ Low system latency
Specification
Host Characteristic | |
OS | WIN7 64-bit |
CPU | Intel I5 |
Display | 15.6-inch HD high-gloss screen |
Memory | 8G |
Storage Method | 120G Solid State Drive |
Mode of Operation | Embedded Mouse and Keyboard |
Transmission Characteristics | |
Frequency | 1400MHz-1480MHz (350MHz-4GHz customizable) |
Bandwidth | 2M/5M/10M/20MHz/40MHz |
Output Power | 36dBm (4W MIMO 2x2) |
Modulation |
DSSS/CCK BPSK/QPSK OFDM BPSK/QPSK/16-QAM/64-QAM |
FEC Code | 1/2,2/3,3/4,5/6) |
Digital Sensitivity | 96dBm@5MHz BPSK |
Data Rate | Up to 80Mbps |
Network Capabilities | 9 hops and no less than 50 nodes |
Data Characteristics | |
RF Interface | N*2,SMA*2 |
LAN Interface | RJ45 Waterproof Interface |
Intercom Interface | 7-pin Lemo Connector |
Video Output | HDMI |
Power Input | 3-pin Aviation Connector |
4G Function | Full Network Access |
Signal Indicator | 1x Dual Color Signal Indicator |
Power Switch | Self-resetting Switch with Light |
Encryption | AES256 |
Electrical Characteristics | |
Voltage & Current | DC12 V, ≤ 3A |
Power Consumption | Average 337dBm |
Battery Capacity | 15.6AH |
Physical Characteristics | |
Operating Temperature | -20~+55℃ |
Storage Temperature | -40℃~ +65℃ |
Dimensions | 577*353*211mm |
Weight | 14.8kg(w/ Battery) |
IP Level | IP65 |
Dimensions
577 x 211 x 353mm
Interface Description
① MESH Antenna Interface
② Antenna Interface (Reserved)
③ Data Interface (Reserved)
④ LAN Port (RJ45)
⑤ Power Input Port
⑥ Screen
⑦ Battery Display
⑧ USB Ports
⑨ Power Switch
⑩ Keyboard
⑪ WIFI Antenna Interface
⑫ 4G Antenna Interface
⑬ SIM Card Slot
⑭ Mic Interface
⑮ Signal Indicator
⑯ Display Switching Panel
Application Scenario
Topology Diagram
■ Star Type
■ Mesh Type
■ Random Type
A MANET system is a group of mobile (or temporarily stationary) devices which need to provide the ability to stream voice, data, and video between arbitrary pairs of devices utilizing the others as relays to avoid the need for infrastructure.
There are many techniques which are employed in order to provide robust MANET capability, including the following:
Self-Forming / Self-Healing is a crucial characteristic of MANET systems. In a true mesh network, radios can join or leave the network at any time, and the network will continuously adapt its topology as nodes move in relation to one another. This implies a decentralized architecture in that there are no central “master” hub radios required to administer control of the network, and communications will continue to persist even when one or more nodes are lost.
Link Adaptation is the ability for each radio to optimally configure its transmission parameters (constellation, FEC coding, and MIMO techniques) to maximize the data rate and robustness of the links to each of the other radios it is communicating with. A particular radio may communicate with another close by radio using a data rate of over 50 Mbps, while using a rate of only 2 Mbps to provide a robust link to a radio much further away. These are packet burst rates, where using a 50Mbps burst is very useful even for a much lower rate data stream because it leaves free channel airtime for other nodes in the network to use. Having high potential data burst rates is important because the less airtime is consumed for the shorter links, the more airtime is left to use slower and much more robust modulation and coding on the distant links.
Adaptive Routing is a mechanism for determining which potential relay paths are used when a stream of data needs to be sent between a given pair of radios. It needs to support self-forming self-healing functionality by adapting dynamically to use all radios present as potential relays and be resilient to the loss of relaying radios. It must also work in conjunction with the link adaptation because determining the optimal route for a stream of data requires consideration of other data which is flowing through the network, as well as the dynamic capacity of each link within the network. This problem is complex and requires all radios to share information about the data traffic flowing through them and the link capacity from each to the other neighboring nodes. This sharing of information must be done in an intelligent manner so that it does not consume too much of the precious available network throughput.
Transparent IP Networking means that any number of standard computer, IP video camera or other devices may be connected to each of the mobile radios and communicate through the mesh network just as if all of the devices were in a single office with wired Ethernet. There are different ways this can be accomplished within the MANET. To enable the most flexibility and ease of use, the best choice is to have the entire MANET network appear as if it is a single Layer 2 networking switch. This means that without any reconfiguration of IP addresses or other settings, a group of IP based devices that work together on a simple Ethernet switch can be connected to MANET radios and resume operations with the new freedom of wireless mobility.
Multicast Traffic presents a set of unique challenges for MANET systems. The multicast support implemented in basic wired Layer 2 switches is to replicate multicast packets coming into one port on all of the other ports. For instance, if an IP video camera is connected to one port it would send its video using packets tagged as multicast. Then computers wired to any of the other ports of the switch can tap into the wireless video stream. This simplistic method turns out to not work very well in a wireless network acting as a Layer 2 switch because many devices within the network might not need to see a particular multicast, and blindly sending the multicast to all devices thus congests the limited throughput of the wireless network unnecessarily. More advanced MANET systems allow manual and/or automatic optimization, limiting the transmission of multicast to only those devices that need a particular multicast stream.
Multi-channel Networks is an advanced capability of some MANET systems which allows a network to utilize multiple RF channels or even multiple frequency bands within a network while still providing the plug and play functionality of a single Layer 2 switch. A simple example of the usefulness of this might be a scenario where soldiers have radios operating on one frequency while vehicles have radios not only operating on that frequency but also ones in a different band. This additional band might be with higher power or higher gain antennas to provide a high speed “backbone” layer between the vehicles. Any soldier’s radio device can communicate with any other soldier’s radio over the air, but the secondary layer on a different frequency can reduce congestion on the soldier frequency and increase to area covered by the network.
All of these MANET networking capabilities combine to provide robust high speed connectivity similar to what is offered by state of the art 3G/4G networking, but in mission critical operational scenarios where permanent wireless infrastructure is not available.
About LinkAV
Founded in 2005, LinkAV has been dedicating to design and manufacture mobile wireless video/data transmission systems including COFDM, IP MESH and 4G-LTE series, with a group of professional engineers to provide tailor-made service (OEM). LinkAV serves a diverse, high demanding customer base from police/ to ordinary citizens, from UAV to UGV/Robots, from oil field to forest, from overseas to mainland China.
LinkAV is a China leading manufacturer (OEM) of innovative wireless communications and information systems. Our advanced data link systems are ideal for critical communications in unmanned systems such as unmanned ground vehicles (UGVs), unmanned aerial vehicles (Drones, UAVs) and unmanned surface vehicles (USVs), and are designed with portability and reliability foremost in mind.
Our Advantages
■ Over 15 years experiences in wireless communication solutions.
■ High product quality, competitive price and low MOQ
■ Excellent pre-sale and after-sale technical team.
■ Quick response and fast delivery.
■ OEM supported.
FAQ
Q1: Are you a manufacturer or a trading company?
We're professional manufacturer specializing in wireless transmission systems.
Q2: Why should I choose you?
You'll get competitive price, prime quality, satisfied service and long warranty.
Q3: What kind of product service can I have?
OEM & ODM service.
Q4: What kind of warranty do you offer?
We offer one-year-warranty and lifelong maintenance.
Q5: What're the payment terms?
We accept bank transfer, PayPal, or cash payment.
Q6: Packaging & Shipping?
Neutral brown carton & Ship via DHL, FedEx, UPS, TNT or by air/sea.
Q7: How long for delivery?
1-3 weeks for regular model and 3-5 weeks for customized model.
Q8: Can I order 1 sample for test?
Yes, we welcome sample order, mixed samples are acceptable.
Q9: Do you have any MOQ limit?
No limit, 1pc is acceptable.
Q10: Is it OK to print my logo on the product?
Yes, please inform us formally before production and confirm the design firstly