Ruggedized Router

Ruggedized Router

The Meizo R68J is a ruggedized enterprise-grade Category 6 4G LTE Router with LTE-Advanced support. With 2 LAN ports and Extended Range WiFi, it provides more connectivity options and flexibility for those looking to get the most out of their high-speed internet experience. The router CPU is...
Chat Now

Product Details

The Meizo R68J is a ruggedized enterprise-grade Category 6 4G LTE Router with LTE-Advanced support. With 2 LAN ports and Extended Range WiFi, it provides more connectivity options and flexibility for those looking to get the most out of their high-speed internet experience. The router CPU is using Broadcom chipset, integrated with Ethernet, SIM, VPN, VRRP, WiFi, and Serial port services. By owning hardware and software watchdog, ensures the router to access internet all the time.

image001.jpg

Main Features

Hardware Specifications

Software Functions

● Support public and private APN network
● Dedicated hardware and software watchdog are designed to support system running reliable.
● ICMP detection and Heartbeat detection ensure the router to be always on line.
● Reboot the router remotely via SMS.
● Incorporate Virtual Router Redundancy Protocol (VRRP), facilitating 3G/4G WAN backup services to existing fixed line routers, providing both WAN and router redundancy to critical business applications.
● Offers business grade security and advanced routing features IPSec (3Des and AES), L2TP, PPTP, GRE as standard.
● Low-voltage, over current, over voltage, anti-reverse protection
● Wide Power Input DC7-36V
● Standard RS232/485 interface to connect with serial devices.
● Router Factory Default Settings can be configured freely.
● System logs can be viewed from local or remote.
● Support WLAN(300Mbps 802.11b/g/n)
● Support SNMP v1/v2/v3
● LEDS for status monitoring (showing Power, System, Internet, VPN, Signal strength).

CPU
● RAM:512Mbit FLASH:128Mbit
Power
● Input DC 7-36V(Standard DC12V)
Environment
● Storage temperature:-40℃~80℃
● Work temperature:-30℃~70℃
● Humidity:<95%
Dimension
● Unit size L*W*H:150*116.2*23.8mm
● Metal Shell, IP30
● Package weight:830g
Interface
● 1 SIM card slot
● 2 LAN 10/100Mb RJ45 port
● 1 RS232 or RS485 serial port
Antenna(female)
● ANT1 for Cell, ANT2,3 for WiFi
EMC
● Electrostatic discharge immunity:EN6100-4-2, level 2
● RFEMS:EN6100-4-3, level 2
● Surge:EN6100-4-3, level 2
● PFMF:EN6100-4-6, level 2
● Shockwave immunity:EN6100-4-8, Horizontal / vertical direction 400A/m(>level 2)
Physical property
● Shockproof:IEC60068-2-27
● Drop test:IEC60068-2-32
● Vibration test:IEC60068-2-6

VPN
● IPSec client
● PPTP client
● L2TP server and client
● GRE client
WIFI
● Transmitting power: 17dbm
● Distance:Cover a radius of 100 meters in open area test
● Allow 50 users to access in theory
NAT
● Port Mapping
● Port Triggering
● DMZ
Firewall
● IP filtering
● MAC filtering
● URL filtering
QOS
● Manage uplink/downlink bandwidth via port or IP
Management
● Web
● Telnet
● TR-069 platform
Routing
● Static Routing
● Policy-Based Routing.
● Dynamic Routing


Model

Frequency & Band

Bandwidth(UL/DL)

Consumption

WiFi (-W)

Serial(-S)

Power

R68J

● FDD-LTE: 2100MHz(B1), 1800MHz(B3), 850MHz(B5), 2600MHz(B7), 900MHz(B8), 800MHz(B18), 800MHz(B19), 1500MHz(B21), 700MHz(B28),
● TDD-LTE: 2600MHz(B38), 1900MHz(B39), 2300MHz(B40), 2500MHz(B41)
● WCDMA: 2100MHz(B1), 850MHz(B5), 850MHz(B6), 900MHz(B8), 1700MHz(B9), 850MHz(B19)
● TD-SCDMA: B39

FDD-LTE:50Mbps/300Mbps
TDD-LTE:10Mbps/112Mbps
DC-HSPA+: 5.76Mbps/42Mbps

Work:0.46A@12V DC
Peak:0.58A@12V DC

802.11n 300Mbps Option

RS232/RS485 Option

US/EU standard
Input: AC100~240V
Output: DC12V Option

R68A
(America)

● FDD-LTE: 2100MHz(B1),1900MHz(B2), 1800MHz(B3),AWS(B4), 850MHz(B5), 900MHz(B8),700MHz(B12), 700MHz(B13), 700MHz(B17), 800MHz(B20) ,1900MHz(B25) 800MHz(B26), 700MHz(B29), 2300MHz(B30)
● TDD-LTE: 2500MHz(B41)
● UMTS/HSPA+: 2100MHz(B1), 1900MHz(B2), AWS(B4), 850MHz(B5), 900MHz(B8) 

FDD-LTE:50Mbps/100Mbps
DC HSPA+:5.76Mbps/42Mbps

Work:0.41A@12V DC
Peak:0.50A@12V DC





ATM (Asynchronous Transfer Mode) Tutorial-Network Architecture,cell,addressing,interfaces
This page of tutorials section covers ATM (Asynchronous Transfer Mode) tutorial. It covers ATM cell, ATM addressing formats, ATM network architecture and ATM network interfaces etc. The Asynchronous Transfer Mode tutorial provides link to ATM protocol layers, ATM services etc.


In the year 1980, ITU-T has initiated efforts to develop a network which can transport voice, video and data simultaneously from source to destination. As a result B-ISDN (Broadband Integrated Services Digital Network) has been developed. The B-ISDN combines telephony network, data network and cable TV network in a single network. ATM as well as SONET/SDH are behind the success of B-ISDN.


image003.jpg


The same is shown in the figure-1. Unlike Synchronous Transfer Mode where in each source will get periodic assignment of bandwidth similar to TDM, Source in ATM packetizes data into smaller fixed size cells and cells are sent only if there is data to be transmitted. In ATM each of the cells will have its own header as described later.


image005.jpg

Following are the silent features of ATM (Asynchronous Transfer Mode):

• ATM uses Virtual Circuit Packet Switching. It reserves capacity for the virtual circuit.
• Packets are known as cells in ATM. The smaller packets are good for voice as well as video transmissions. One ATM cell consists of header (5 bytes) and data payload (48 bytes).
• It allows multiple logical connections to be multiplexed over single physical interface.
• It is a connection oriented technology.
• As mentioned it provides dynamic allocation of bandwidth for efficient traffic management.
• Supports minimum flow control and error control capabilities.
• Supports LAN, CAN and WAN
• ATM can be deployed in private, public or hybrid networks.


image006.jpg


• In ATM (Asynchronous Transfer Mode) logical connections are known as virtual channel connections or VCCs. The VCC is similar to virtual circuit (VC) in packet switched network. It is unit of switching used in ATM network.

• Initially VCC is established between end users in the network.

• After the VCC connection is established variable rate and fixed size cells are exchanged.

• Here VPC i.e. Virtual Path Connection is combination of VCCs having same end points or destinations. Hence all the ATM cells travelling through VCCs in one common VPC are switched together.

• Virtual path is identified by VPI and Virtual Channel is identified by VCI as mentioned below.
➨VPI (Virtual Path Identifier) identifies virtual path (8/12 bits in size).

➨VCI (Virtual Channel Identifier) identifies virtual channel in a virtual path (16 bits). 


ATM Network Architecture and network interfaces

image008.jpg

• The figure-2 depicts ATM (Asynchronous Transfer Mode) network architecture with interfaces. There are two types of Virtual connections supported by ATM network viz. PVCs and SVCs.

• PVCs are referred as Permanent Virtual Connections. They are similar to leased lines used between users. The PVCs are set up by the operator.

• SVCs are referred as Switched Virtual Connections. They are set up and teared down based on end user demand.

• The ATM network interfaces include UNI (User-Network Interface) , NNI (Network-Network Interface) and B-ICI (Broadband Intercarrier Interface). User interacts with network using UNI interface to establish SVC connection. The ATM switches interact using NNI interface in order to exchange information. ATM switches belonging to another public networks will communicate using B-ICI interface.


ATM Cell-UNI cell vs NNI cell

As mentioned earlier ATM cell is composed of header and payload part. Header is of size equal to 5 bytes or octets and payload which carrier information from upper layers is of size equal to 48 bytes. Header of ATM (Asynchronous Transfer Mode) cell varies in UNI interface and NNI interface. The same have been shown in the figure below. Let us understand difference between UNI cell header and NNI cell header. As shown, GFC field is used only in UNI cells. At NNI, GFC byte is used to incorporate additional VPI.


image010.jpg

UNI Cell Header field

Size

Description

GFC

4 bits

Generic Flow Control

VPI

(8 bits for UNI or 12 bits for NNI)

Virtual Path Identifier, It is a routing field for the network.

VCI

16 bits

Virtual Channel Identifier, It is used for routing to and from end user. It acts as SAP(Service Access Point).

PT

3 bits

Payload Type

CLP

1 bit

Cell Loss Priority , value of 0 indicates that cell should not be discarded. Value of 1 indicates that cell can be discarded.

HEC

8 bits

Header Error Control, It is used to correct single bit errors in the header. It is also used to detect double bit errors.


NNI Cell Header field

Size

Description

VPI

8/12 bits

Virtual Path Identifier

VCI

16 bits

Virtual Channel Identifier

PT

3 bits

Payload Type

CLP

1 bit

Cell Loss Priority

HEC

8 bits

Header Error Control


ATM Addressing Formats-DCC, ICD, E.164

image012.jpg

All the ATM (Asynchronous Transfer Mode) addresses are of 20 byte in size. Source and destination addresses are used while establishing a connection. There are three types of formats used for ATM address viz. NSAP (Network Service Access Point), DCC and ICD.
• ATM end points use NSAP format. ISDN telephone numbers use the format E.164.
• DCC (Data Country Code) format is used for public networks.
• ICD international Code Designator) format is used for private networks.
Following table describes fields used in ATM addresses.


Field

Size

Description

AFI

1 byte

Authority and Format Identifier, tells which addressing scheme is used.

IDI

2-8 bytes

Initial Domain Identifier, Identifies a domain within scope of addressing authority.

HO-DSP

4-10 bytes

high Order bits of domain specific part, same as network prefix of IP address

ESI

6 bytes

End System Identifier, Same as host number of IP address

SEL

1 byte

Selector, for endsystem use only


ATM Protocol Stack

image014.jpg

ATM protocol stack consists of three main layers viz. AAL Layer, ATM layer and physical layer. Above AAL layer upper layers reside. Following are the functions of each.

➨AAL layer does encapsulation of user level data. AAL layer breaks the upper layer data at the sender side into small size ATM cells and reassembles the cells at the receiver side.

➨ATM layer take care of transport of 53 byte ATM cells created by AAL layer across the ATM network. It does multiplexing of multiple logical channels on one single physical channel. It provides different services for ATM cells.

➨ATM physical layer does encoding (at transmit end) and decoding (at receive end) of bits based on physical medium used for transportation of ATM cells.


Inquiry