The Meizo R58 outdoor 4G router CPU is using Industrial Grade equipment design standards, passed CE, FCC and EMC test, stable and reliable. Multiple VPN encryption protocols as L2TP, IPSec, PPTP and GRE are owned, making it readily ideal for delivering optimal network connectivity to all oil and mining site, as well as serving as the reliable communication backbones for critical communication applications. Instant POS Setup for Credit Card Access in Remote Area. Its CPU is using Broadcom chipset, integrated with industrial grade 4G modem, offering WAN, LAN, SIM, VPN, VRRP, WiFi, and Serial port services, product line supporting the following radio access technologies: LTE, HSPA+, HSPA, UMTS, EDGE, CDMA2000, GPRS . By owning automatic connection monitoring and heartbeat detection, make sure the router to be always online.
The R58 4G/LTE products have thousands of installed bases in China, North America, South East Asia, Africa and other areas, too. Our outdoor 4G/LTE routers offer superior RF and antenna engineering for maximum LTE performance, as well as comprehensive networking solutions that are ready to be utilized in a diversity of revenue generating applications and vertical markets.
Main Features |
Hardware Specifications |
Software Functions |
● Support public and private APN network |
CPU |
VPN |
Model |
Frequency & Band |
Bandwidth(UL/DL) |
Consumption |
WiFi (-W) |
Serial(-S) |
Power |
R58A |
● FDD-LTE: 2100MHz(B1),1900MHz(B2), 1800MHz(B3), AWS(B4), 850MHz(B5), 2600MHz(B7),700MHz(B12),700MHz(B13), 800MHz(B20), 1900MHz(B25) , 850MHz(B26), 700MHz(B29), 2300MHz(B30), |
FDD-LTE:50Mbps/300Mbps |
Work:0.46A@12V DC |
802.11n 300Mbps Option |
RS232/RS485 Option |
US/EU standard |
R58C |
● FDD-LTE: 2100MHz(B1), 1800MHz(B3), 900MHz(B8) |
FDD-LTE:50Mbps/150Mbps |
Work:0.41A@12V DC |
|||
R58E (Europe & Asia network) |
● FDD-LTE: 2100MHz(B1), 1800MHz(B3), 850MHz(B5), 2600MHz(B7), 900MHz(B8), 800MHz(B20) |
FDD-LTE:50Mbps/150Mbps |
Work:0.41A@12V DC |
|||
R58J |
● FDD-LTE: 2100MHz(B1), 1800MHz(B3), 850MHz(B5), 2600MHz(B7), 900MHz(B8), 800MHz(B18), 800MHz(B19), 1500MHz(B21), 700MHz(B28), |
FDD-LTE:50Mbps/300Mbps |
Work:0.46A@12V DC |
Difference between M2M and IoT
The M2M means machine to machine communication. It is also a data communication standard. It involves one or more entities. This technology makes it possible for smart devices to communicate via internet connection using IP protocols.It enables data flow between human being and machines and also between machines and machines.
M2M is also named as Machine Type Communication (MTC) in 3GPP. Following section explains M2M high level system architecture.
Figure describes 4 phases involved in M2M technology.It covers collection of the data, transmission of the data through the communication medium/network, assessment of the data collected and response to the machine based on the assessment.
Let us take example of smart meter to understand the M2M concept. Smart meter records the electricity rate which will be communicated to the software application over some medium using internet. This application process the data sent by the smart meter and decides whether the consumer device can be switched on at this time or at later stage to conserve the energy. Hence smart electricity meter here acts as interface between both consumer as well as for electric company to save the energy and save the money.
M2M system support a mechanism to manage and interact with multiple M2M Applications. The M2M system Architecture consists of following:
• M2M Applications
• M2M Transport network, which covers Access network,core network(CN) and M2M service capabilities
The architecture is devided into M2M Device domain, and a Network and applications domain.
M2M Applications
The cellular based M2M solutions provide easier installation and provisioning targetted mainly for short term deployments. M2M communication could be carried over mobile networks (e.g. GSM-GPRS, CDMA EVDO networks). In the M2M communication, the role of mobile network is largely confined to serve as a transport network.
M2M devices vary from highly-mobile vehicles communicating in real-time, to im-mobile meter-reading appliances that send small amounts of data at random instants.
It covers the communications between the M2M Gateway(s) and M2M application(s), e.g. xDSL, LTE, WiMAX, and WLAN.
Other than cellular M2M is widely adopted in energy,transport,real estate and agriculture sectors. As mentioned previously smart meter utilizes the energy efficiently and hence bring down CO2 emissions. Hence M2M helps in lowering the effect of global warming.
In the transport sector M2M helps by providing information regarding best optimized routes to trucks,ships,trains and planes so that wastage of fuel can be avoided. This also helps reduce CO2 emissions by cutting the distance of the travel.
M2M helps in building and home management by conserving energy for various systems viz. cooling, lighting,heating,ventillation and other electronic appliances. It also provides security for the home or building owner with the M2M compliant security enabled devices.
In agriculture sector M2M provides solutions to monitor cattle health and grazing style, soil monitoring,smart farming and smart watering. This helps grow large amount of crops with lesser resources and hence save money for the farmers.
As we know that IoT will use existing internet infrastructure to connect the objects,things, devices other than the people. IoT applications are enormous and it will be used in medical,retail,military,consumer, agriculure,environmental,automotive and industrial need.
In the IoT network, all the devices are connected to the internet with separate IP address.IPv4 is not enough to address the demand of internet enabled devices in the IoT space. Hence IPV6 was developed to address the demand of huge number of IP addresses. Currently major challanges addressing the requirement of IoT devices are deployment of IPV6 across the world and requirement of prolonged battery life. The other requirement is increase in the receiver sensitity level of RF ICs and not but the least the cost. The cost of the IoT device should be less than about 5 to 6 dollar to capture the big IoT market.
As mentioned IoT network consists of front end and back end. Back end is entirely digital internet hardware and software. Front end consists of mainly sensors. Following are IoT components used in IoT device as well as for sensing applications.
IoT components include Sensors, power management devices,amplifiers,signal acquisition devices,microcontrollers,processors,battery monitoring ICs, low power RF ICs and more. sensors are used for temperature,motion,humidity,acceleration,tilt,pressure,shock,gas,pH,sound and infrared applications. Refer IoT sensors page for more information.
IoT goes beyond the M2M periphery and it basically represents things connecting with the systems,people and other things.
M2M can be thought of as integral to the IoT. IoT is bigger than M2M.