RV54 Manual
Connecting with the device to the System (Laptop/Desktop)
To log in to SILBO_RV54 by connecting the router to your laptop or desktop via LAN or using Wi-Fi, please follow the steps below.
Connecting via LAN:
Connect your laptop's LAN port to one of the router's LAN interfaces. Ensure that you select any LAN interface (there are 4 available) while making sure the WAN interface is not used.
How to connect with the SILBO_RV54 application
Once the LAN connection is established between the device and the laptop or the desktop
Please open the command prompt and ping to get the IP config of that device.
Type the command Ipconfig
It will provide the Ip address/url of that device through which the application can be accessed.
Log In
Open the web browser and type the IP address in the URL.
It will show the log in page of the application.
Give the valid credentials for the username and password to login to the application page.
Once the user credentials are provided it will direct to the landing page of the application.
The “Status” landing page shows all the detailed specification of the device like system, memory storage and connection tracking etc.
The application is divided into 6 Modules.
- Info
- Status
- Settings
- Features
- Maintenance
- Routing
- Logout
1. Info
The “Info” module provides the information about the devices to the user.
It provides all the specification related to the hardware, firmware, Networks and the Connection uptimes.
It has 3 submodules.
- Overview
- System Log
- Kernel Log
1.1 Overview
In overview module it displays all the specification categorically of a device like System, Memory, storage, Connection tracking, DHCP Lease.
System:
In this section it displays the hardware configured specification of the device.
The specifications details are as follows,
SN | Field name | Sample value | Description |
1 | Hostname | 41B01240016 | This field displays the router serial number of the device |
2 | Model |
|
This field displays the model number of the device |
3 | Firmware Version and IPK Version | 1.09_1.09 | This field displays the firmware version and IPK version |
4 | Kernel Version | 5.4.215 | This field displays the kernel version of the device |
5 | Local Time | Monday, August 19, 2024 at 11:17:10 AM | This field displays the local time |
6 | Uptime | 0h 27m 29s | This field displays the uptime of the device |
7 | CPU Load Average | 0.29 (last minute) |0.21 (last 5 minutes) | 0.19 (last 15 minutes) | This field displays the CPU average load |
Memory:
In this section it displays the memory configured specification of the device.
The specifications details are as follows.
SN | Field name | Sample value | Description |
1 | Total Available | 68676 kB / 124208 kB (55%) | This field displays the total availability of memory space in the device |
2 | Free | 59344 kB / 124208 kB (47%) | This field displays the Free memory space in the device |
3 | Cached | 312 kB / 124208 kB (0%) | This field displays the Cached memory space in the device |
4 | Buffered | 9332 kB / 124208 kB (7%) | This field displays the Buffered memory space in the device |
Storage:
In this section it displays the status of storage as root and temporary usage specification of the device.
The specifications details are as follows.
SN | Field name | Sample value | Description |
1 | Root Usage |
|
This field displays the total root usage of the device |
2 | Temporary Usage |
312 kB / 62104 kB (0%) |
This field displays the total temporary usage of the device |
Network:
In this section you can check as to whether you are connected to IPV4 or IPV6 Network.
Since this a 5G Module, both 4G and 5G Network can be latched.
IPV4 = 4G Network
IPV6 = 5G Network
Connection Tracking:
In this section it displays the status of connection tracking for the device.
DHCP Leases:
In this section it displays the DHCP lease of the temporary assignment of an IP address to a device on the network.
The specifications details are below.
SN | Field name | Sample value | Description |
1 | Host Name | KermaniK-LT | This field displays the configured Host Name/Username for that device. |
2 | IPv4-Address | 192.168.10.147 | This field displays the IP address of the device. |
3 | MAC-Address | 34:73:5a:bb: ab:7a | This field displays the MAC-Address of the device. |
4 | Lease time remaining | 11h 53m 49s | This field displays the lease time remaining for the device. |
1.2 System Log
This page provides on screen System logging information. In this page the user gets to view the system logs.
1.3 Kernel Log
This page provides on screen Kernel logging information.
In this page the user gets to view the Kernel logs.
2.Status
In this module the user can view the status of the router device with respect to the network, Wan, modem etc.
It has 4 submodules.
- Interfaces
- Internet
- Modem
- Routes
2.1 Interfaces
Each network device (interface) is associated with specific traffic statistics, uptime, and status. Active interfaces are operational, while inactive interfaces are not currently transmitting data.
Looking on the network status the user can check if the cellular, Wi-Fi, Ewan, VPN etc is up.
2.2 Internet
In this submodule the user can view the status of the internet connections.
To see the latest status of the internet connection the user needs to click on the refresh button.
2.3 Modem
This modem status page provides comprehensive information about the cellular connection's network operator, technology, mode, and various signal quality metrics.
2.4 Routes
This configuration shows how the router directs traffic between different networks and interfaces, ensuring proper communication within the local network and to external networks via the default gateway.
ARP Table: Maps IP addresses to MAC addresses for devices on the network, helping in identifying which device is on which interface.
IPv4 Routes: This shows which network is directly connected on which interface.
Example: Network 192.168.10.0/24 is directly connected on interface eth0.1.
IPv6 Routes: Similar routes as IPv4, but this time listed under IPv6 routing rules.
Example: Local networks 192.168.10.0/24 and 192.168.100.0/24 are managed through eth0.1 and ra0, respectively.
3. Settings
In this “Setting” module the user can Configure/update all the required parameters related to Network, Internet, VPN, Firewall, Traffic Shaping, Loopback Rule, Remote monitoring, Tunnel as per requirement.
IT consist of 11 submodules.
- VLAN
- Network
- Multi-WAN
- VPN
- Firewall
- SIM Switch
- Traffic Shaping
- Loopback Rule
- VRRP
- Remote Monitoring
- Tunnel
3.1 VLAN
VLAN (Virtual Local Area Network) is a network within a network that segregates traffic into different logical networks on the same physical hardware. VLANs help in managing traffic more effectively and securely.
It is further divided into 2 sections,
Port-Based VLAN
Tagged Port Configuration
Port-Based VLAN:
A VLAN configuration method where network ports are assigned to specific VLANs.
EDIT:
To add a new VLAN ID, click on ‘Add Device’.
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | VLAN ID | 1 | This is a unique identifier for a VLAN within a network. |
2 | Port 0 | Untagged | When a port is set as untagged for a VLAN, it means that traffic entering or exiting this port is automatically associated with that VLAN without any VLAN tags being added to the frames. |
3 | Port 1 | Untagged | |
4 | Port 2 | tagged | When a port is set as tagged for a VLAN, it means that traffic on this port will include VLAN tags in the Ethernet frames. These tags carry the VLAN ID, allowing switches and other devices to know which VLAN the traffic belongs to. |
5 | Port 3 | Untagged | |
6 | Port 4 | OFF | When a port is marked as off for a VLAN, it means that the port is not participating in that VLAN at all. It will neither send nor receive traffic associated with that VLAN. |
Save and update the page.
Tagged Port Configuration:
EDIT:
To add a new VLAN ID, click on ‘Add Device’.
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Type | 802.1Q | IEEE 802.1Q is the standard protocol for VLAN tagging in Ethernet networks. |
2 | Parent Interface | Port 2 | It is the underlying physical interface like port 2 that carries the VLAN-tagged traffic. |
Save and update the page.
3.2 Network
In this section the user does all the setting related configuration with reference to network like Ethernet
Settings, Cellular Settings, Band lock and Operator Lock, Wi-Fi Settings, Guest Wi-Fi etc.
Ethernet Settings:
In this page it will display all the configured port that is attached with the device.
For this device 5 ports are configured.
Ethernet mode can be configured as WAN and as LAN as well.
Ethernet LAN Connection settings can be configured as DHCP, Static and PPOE.
Note: if required, add an interface in Internet page under Settings
EDIT:
To add a new Interface, click on ‘Add’.
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the update button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below: Type: WAN
SN | Field Name | Sample Value | Description |
1 | Physical Device | Ex: eth0.5 | This indicates a network interface on which our network is connected. This setting is by default (Editable). |
2 | Type | WAN/LAN | This designates whether the interface is part of the WAN or LAN.
WAN: Connects the device to the internet. LAN: Connects the device to the internal network. |
Protocol: Static | |||
3 | Static IP Address | Ex: 192.168.1.10 | The manually assigned IP address for the interface. |
4 | Static Netmask | Ex: 255.255.255.0 | Subnet mask corresponding to the IP address. |
5 | Static Gateway | Ex: 192.168.1.1 | The IP address of the gateway (router) that the interface will use to send traffic outside its own subnet. |
Protocol: DHCP | |||
6 | DHCP Gateway | Ex: 10.1.1.1 | The IP address of the DHCP server (often the same as the router or gateway). |
Protocol: PPPoE | |||
7 | Username | Any Name | The username provided by your ISP for PPPoE authentication. |
8 | Password | ***** | The password provided by your ISP for PPPoE authentication. |
9 | Access Concentrator | Typically, the name of the ISP's PPPoE server. | |
10 | Service Name | Sometimes required by ISPs, this field specifies a particular service offered by the ISP. | |
11 | Gateway | Ex: 0.0.0.0 | The IP address used as the default route. |
12 | MAC Address | Ex: D0:93:95:B0:98:6B | The hardware (MAC) address of the network interface. This is unique to every network device. |
13 | Override MAC Address | Ex: D0:93:95:B0:98:6B | This field allows you to manually set a different MAC address if needed.
If left blank, the default MAC address is used. |
14 | Create Firewall Zone | Enable/Disable | You can assign this interface to a particular firewall zone, which determines its access rules (e.g., WAN zone for internet traffic, LAN zone for internal traffic). |
Advanced Settings: Enable/Disable | |||
15 | Broadcast | Ex: 192.168.123.34 | Broadcast address for the network, typically calculated based on the IP and subnet mask. |
16 | Override MTU | Ex: 1500 | MTU size controls the maximum packet size that can be sent over the network.
Default is usually 1500 bytes. |
17 | Delegate | Enable/Disable | If checked, it allows delegation of prefixes for IPv6, often left unchecked unless needed. |
18 | Force Link | Enable/Disable | Forces the interface to be up even if no physical link is detected. |
19 | IPv4 Route Table | Enable/Disable | This field is used to specify static routes for IPv4. |
20 | Table No. | 254: Default main routing table.
100: Custom routing table for specific purposes. |
Default Table (Main Table): Usually, there is a default routing table (often Table No. 254 or 255) where all the routes are stored by default.
Custom Table: You can specify a different table number if you are managing multiple routing policies (e.g., VoIP traffic, VPN traffic). |
Type: LAN
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Physical Device | Ex: eth0.1 | This is the network interface identifier. |
2 | Type | WAN/LAN | This designates whether the interface is part of the WAN or LAN.
WAN: Connects the device to the internet. LAN: Connects the device to the internal network. |
3 | Protocol | Static | This means that the IP address, netmask, and other network settings are manually configured rather than being automatically assigned by a DHCP server. |
4 | IP Address | Ex: 192.168.10.1 | This is the static IP address assigned to the interface. It acts as the gateway IP address for devices connected to this LAN. |
5 | Static Netmask | Ex: 255.255.255.0 | This is the subnet mask for the network. |
6 | MAC Address | Ex: D0:93:95:B0:98:6C | This is the hardware (MAC) address of the network interface, which uniquely identifies this device on the network. |
7 | Override MAC Address | This allows you to manually enter a different MAC address if needed. | |
8 | Enable DNS | Enable/Disable | If this option is enabled, the interface will act as a DNS resolver for the devices on the LAN, using the specified DNS server. |
9 | DNS Server Address | Ex: 8.8.8.8 | This is the IP address of the DNS server that will be used by devices on the LAN to resolve domain names to IP addresses.
More than one DNS Address can be added. |
10 | Enable DHCP Server | Enable/Disable | If enabled, this setting allows the interface to function as a DHCP server, automatically assigning IP addresses to devices connected to the LAN. |
11 | DHCP Start Address | 70 | The DHCP server will begin assigning IP addresses starting from 192.168.10.70 |
12 | DHCP Limit | 100 | This specifies the number of IP addresses the DHCP server can assign. Starting at 192.168.10.70 and with a limit of 100, the server can assign addresses up to 192.168.10.169. |
13 | Lease Time Duration | Hours-(H)
Minutes-(M) Seconds-(S) |
Hours-(H): This indicates that the lease time for each IP address assignment is measured in hours.
Minutes-(M): This indicates that the lease time for each IP address assignment is measured in minutes. Seconds-(S): This indicates that the lease time for each IP address assignment is measured in seconds. |
14 | Lease Time | 12 | The DHCP lease time is set to 12 hours. After this period, a device must renew its IP address lease with the DHCP server to continue using the assigned IP address. |
15 | Create Firewall Zone | Enable/Disable | You can assign this interface to a particular firewall zone, which determines its access rules (e.g., WAN zone for internet traffic, LAN zone for internal traffic). |
16 | Internet Over SW_LAN | Enable/Disable | Allow all outbound traffic from the LAN to the internet. |
Advanced Settings: Enable/Disable | |||
17 | Broadcast | Ex: 192.168.123.34 | Broadcast address for the network, typically calculated based on the IP and subnet mask. |
18 | Override MTU | Ex: 1500 | MTU size controls the maximum packet size that can be sent over the network.
Default is usually 1500 bytes. |
19 | Delegate | Enable/Disable | If checked, it allows delegation of prefixes for IPv6, often left unchecked unless needed. |
20 | Force Link | Enable/Disable | Forces the interface to be up even if no physical link is detected. |
21 | IPv4 Route Table | Enable/Disable | This field is used to specify static routes for IPv4. |
Save and Update once configuration changes have been made.
Cellular Setting:
In this page, the user needs to configure the various details with respect to the SIM.
Select single cellular single sim where the user must configure the APN details of the sim used for the router device.
The Configurations can be done based on the SIM usage, with respect to IPV4 or IPV6.
Specification details are given below:
SN | Field name | Sample value | Description |
1 | Cellular Enable | Checkbox | Check this box to enable cellular functionality. |
2 | Cellular Operation Mode | 1.) Single Cellular with Dual Sim
2.) Single Cellular with Single SIM |
1.) This mode allows you to use one cellular modem with two SIM cards.
2.) This mode allows you to use one cellular modem with single SIM card. |
3 | Cellular Modem 1 | QuectelRM500U | This field displays the modem name. |
4 | Choose SIM 1 APN Mode | 1.) Auto
2.) Manual |
1.) Choose Auto for regular SIM to detect APN name automatically.
2.) Choose manual to enter the APN settings manually in case of M2M SIM cards. |
5 | SIM 1 Access Point Name | jionet | Enter the APN provided by your cellular service provider in case of M2M sim. For regular sim cards APN name will be displayed automatically. |
6 | SIM 1 PDP Type | IPV6 | Choose the PDP type, which is typically either IPv4 (4G) or IPv6 (5G) depending on the sim card. |
7 | Enable 464xlat for Sim1 | Enable/ Disable | In case of 5G jio sim cards, this option needs to be enabled. |
8 | SIM 1 Username | Enter the username if required by the APN. Leave blank if not required. | |
9 | SIM 1 Password | Enter the password if required by the APN. Leave blank if not required. | |
10 | SIM 1 Authentication Protocol | None | Choose the authentication protocol. Options typically include None, PAP, CHAP, PAP/CHAP. |
11 | Choose SIM 2 APN Mode | 1.) Auto
2.) Manual |
1.) Choose Auto for regular SIM to detect APN name automatically.
2.) Choose manual to enter the APN settings manually in case of M2M SIM cards. |
12 | SIM 2 Access Point Name | www | Enter the APN provided by your cellular service provider in case of M2M sim. For regular sim cards APN name will be displayed automatically. |
13 | SIM 2 PDP Type | IPV4 | Choose the PDP type, which is typically either IPv4 (4G) or IPv6 (5G) depending on the sim card. |
14 | SIM 2 Username | Enter the username if required by the APN. Leave blank if not required. | |
15 | SIM 2 Password | Enter the password if required by the APN. Leave blank if not required. | |
16 | Enable 464xlat for Sim2 | Enable/ Disable | In case of 5G jio sim cards, this option needs to be enabled. |
17 | SIM 2 Authentication Protocol | None | Choose the authentication protocol. Options typically include None, PAP, or CHAP. |
18 | Primary SIM Switchback Time | 10 min | The system should switch back to the primary SIM if it becomes available. |
Band lock and Operator Lock:
In this page, the user needs to configure the lock band and operator based on the service provider.
Bands available in the drop-down list.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Module | QuectelRM500U | The Quectel RM500U is a 5G module that supports both LTE and NR5G networks. |
2 | Mode Selection | 1.) Automatic
2.) LTE only 3.) NR5G only 4.) NR5G and LTE |
1.) The modem will automatically select the most appropriate network mode based on availability and signal strength. It will switch between LTE and NR5G as needed.
2.) The modem will be locked to LTE (4G) networks only. It will not attempt to connect to NR5G networks, even if they are available. 3.) The modem will be locked to NR5G (5G) networks only. 4.) This mode typically allows for dual connectivity, where the modem can simultaneously use both LTE and NR5G for better performance. |
3 | LTE Band Selection | Ex: LTE B1 | If custom band selection is enabled, users would typically be able to choose specific LTE bands that the modem will use. |
4 | NR5G Band Selection | Ex: 5G B1 | The modem will automatically connect to the best available 5G band based on signal strength and network conditions. |
Click on save and update after changes have been made.
Operator Selection Mode:
The user needs to click on the check box of the “operator select enable” to select the operator.
Once the check box is clicked there will be a dropdown list of the operator modes from which the user needs to select the mode. The user needs to select the operator mode from the given dropdown list.
If the user selects the mode “Manual” or “Manual-Automatic” then one more text box will appear where the user must provide the operator code.
After configuring all the required information, click on save.
Wi-Fi Settings:
Since this is a 5G Module device, there are 2 Wi-Fi settings available,
1.) 2.4Ghz WIFI Settings
2.) 5Ghz WIFI Settings
2.4Ghz WIFI Settings:
Access Point mode: In Access Point mode, a configuration in which a router, allows wireless devices to connect to a wired network by creating a Wi-Fi hotspot.
Client point:
In client mode, the access point connects your wired devices to a wireless network. This mode is suitable when you have a wired device with an Ethernet port and no wireless capability, for example, a smart TV, Media Player, or Game console and you want to connect it to the internet wirelessly, select the Client Mode and give the Radio SSID & client passphrase.
Access point and Client:
Select this option for both type of connection, give both SSID and passphrase.
After configuring all the required information, click on save and update.
Specification details are given below:
SN | Field name | Sample value | Description |
1 | Radio Mode | 1.) Access point
2.) Client only 3.) Access point and Client |
The user must select any radio mode based on the requirement as shown above. |
2 | WirelessMode | 1.) B/G Mixed
2.) B Only 3.) G Only 4.) B/G/N Mode 5.) N_in_2G mode” --, HE Wireless Mode |
1.) This mode allows the access point to support both 802.11b(2.4 GHz with a max data rate of 11 Mbps.) and 802.11g(2.4 GHz with a high max data rate of 54 Mbps) devices.
2.) The access point will only support 802.11b devices. 3.) The access point will only support 802.11g devices. 4.) This mode allows the access point to support 802.11b, 802.11g, and 802.11n(operates at both 2.4 GHz and 5 GHz) devices. 5.) The access point will only support 802.11n devices operating in the 2.4 GHz band. |
3 | Country Code | INDIA | The region is set to India. |
4 | CountryRegion | Ex: 0 (Ch1-11) | Select channels as per requirement. |
5 | Channel | Ex: Auto | Select Channel depending on CountryRegion |
6 | Channel BandWidth | Ex: 20 MHz | The bandwidth is set to 20 MHz, which is common for 2.4 GHz networks. |
7 | TX Power | 100 | Transmit power is set to maximum (100%), ensuring the strongest possible signal. |
8 | Radio SSID | RV54_41B01240016_2.4 | Devices searching for available networks will see this name. |
9 | Radio Passphrase | •••••••• | This is the password for connecting to the Wi-Fi network. |
10 | Radio Encryption | AES | The access point uses AES (Advanced Encryption Standard) for securing wireless communications. |
11 | Radio DHCP server IP | 192.168.100.1 | This will be the default gateway IP for devices connecting to the network (can be changed). |
12 | Radio DHCP start address | 2 | The DHCP server will assign IP addresses starting from 192.168.100.2 (will differ if any changes). |
13 | Radio DHCP limit | 200 | The DHCP server can assign up to 200 IP addresses. |
14 | Client SSID | Any device SSID | The SSID (Service Set Identifier) is the name of the Wi-Fi network you want the device to connect to. |
15 | Client Radio Passphrase | •••••••• | This is the password required to connect to the Wi-Fi network. |
16 | Client Radio Authentication | This setting defines the type of authentication used by the Wi-Fi network. Leave it blank if not in use. | |
17 | Client Radio Encryption | Ex: AES | This determines the type of encryption used to secure data transmitted over the Wi-Fi network. |
5Ghz WIFI Settings:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | WirelessMode | mixed | This mode allows the access point to support multiple Wi-Fi standards, typically including 802.11a(Operates on the 5 GHz band), 802.11n(supports both 2.4 GHz and 5 GHz), and 802.11ac (Designed specifically for the 5 GHz band). |
2 | Country Code | INDIA | Setting this to "INDIA" ensures compliance with local regulations regarding the 5 GHz Wi-Fi spectrum. |
3 | Channel | auto | The access point automatically selects the best available channel based on current Wi-Fi traffic and interference. |
4 | Channel BandWidth | 80 MHz | 20 MHz: The default width for most networks, offering the best compatibility.
40 MHz: Provides more bandwidth, suitable for less congested environments. 80 MHz: Offers the highest throughput but may suffer from interference in crowded environments. |
5 | TX Power | 100 | The transmit power is set to 100%, which is the maximum power output allowed by the device. |
6 | Radio SSID | RV54_41B01240016_5 | This is the name that users will see when searching for available Wi-Fi networks. |
7 | Radio Passphrase | •••••••• | This is the password required to connect to the Wi-Fi network. |
8 | Radio Mode | Access Point | The device is set to operate as an access point, providing wireless connectivity to devices within its range. |
9 | Radio Encryption | 1. NONE
2. WPA Personal (PSK) 3. WPA Personal (PSK) + AES 4. WPA Personal (PSK) + CCMP 5. WPA Personal (PSK) + TKIP + CCMP 6. WPA Personal (PSK) + TKIP + AES |
1.) This option disables encryption on the Wi-Fi network.
2.) This is a basic security option commonly used in home and small office networks. 3.) This is the most recommended option for most networks. It provides strong security by combining the WPA Personal protocol with AES encryption. 4.) This option is technically equivalent to WPA Personal (PSK) + AES, as CCMP is the mode in which AES operates under WPA2. 5.) This is a backward-compatible option that can be used in networks where some older devices only support TKIP, while newer devices can take advantage of the more secure AES (CCMP). 6.) Like the TKIP + CCMP option, this is intended for environments with mixed device capabilities. |
10 | Radio DHCP Server IP | 192.168.200.1 | This IP address will act as the default gateway for devices connecting to the Wi-Fi network. |
11 | Radio DHCP Start Address | 2 | The starting IP address in the DHCP range. The first device that connects will receive 192.168.200.2. |
12 | Radio DHCP Limit | 200 | The maximum number of IP addresses that the DHCP server can assign. In this case, it can assign up to 200 devices. |
After configuring all the required information, click on save and update.
Guest WIFI:
As shown below, this section has 2 modes,
Enable 2.4Ghz Guest Wifi, Enable 5Ghz Guest Wifi
Enable 2.4Ghz Guest Wifi:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable 2.4Ghz Guest Wifi | Enable/Disable | Enable this option if you want to set up a 2.4Ghz Guest Wifi. |
2 | SSID | Guest_2.4Ghz | The SSID field must not be empty. You need to enter a name for the Guest Wi-Fi network. |
3 | Passphrase | Ex: GuestAccess2024 | The passphrase is the password required to connect to the Guest Wi-Fi network. |
4 | Radio DHCP Server IP | Ex: 192.168.110.1 | The DHCP Server IP field must not be empty. You must assign a valid IP address within the subnet range you intend to use for the Guest Wi-Fi network. |
5 | Radio DHCP Start Address | 2 | The starting IP address in the DHCP range. The first device that connects will receive 192.168.110.2. |
6 | Radio DHCP Limit | 100 | The maximum number of IP addresses that the DHCP server can assign. In this case, it can assign up to 100 devices. |
After configuring all the required information, click on save and update.
Enable 5Ghz Guest Wifi:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable 5Ghz Guest Wifi | Enable/Disable | Enable this option if you want to set up a 5Ghz Guest Wifi. |
2 | SSID | Guest_5Ghz | The SSID field must not be empty. You need to enter a name for the Guest Wi-Fi network. |
3 | Passphrase | Ex: Guest5GAccess2024 | The passphrase is the password required to connect to the Guest Wi-Fi network. |
4 | Radio DHCP Server IP | Ex: 192.168.220.1 | The DHCP Server IP field must not be empty. You must assign a valid IP address within the subnet range you intend to use for the Guest Wi-Fi network. |
5 | Radio DHCP Start Address | 2 | The starting IP address in the DHCP range. The first device that connects will receive 192.168.220.2. |
6 | Radio DHCP Limit | 100 | The maximum number of IP addresses that the DHCP server can assign. In this case, it can assign up to 100 devices. |
After configuring all the required information, click on save and update.
Wireless Schedule:
Wi-Fi can be automatically withdrawn based on the configuration done in this section.
The user can schedule the Wi-Fi’s accessibility time during a particular period.
The user can select more than one “day of the week” for scheduling the Wi-Fi working hours as shown above.
After configuring all the required information, click on save and update.
SMS Settings:
User needs to enable SMS option in SMS settings page. This option is to validate the mobile numbers using which controlling commands could be sent to the router device.
1 to 5 mobile numbers can be authenticated by choosing from “Select Valid SMS user numbers” and adding the mobile numbers below respectively.
API key is the pass key used in the commands while sending SMS. Displayed in the below screen is the default API key which can be edited and changed as per choice.
1.) Select valid user number max. 5 and add authorized phone number in the tab where you want to find the alert and click on ‘SMS Response Enable’, ‘save’ and ‘update’ button.
2.) Now send SMS commands from the configured mobile number.
3.) Once the commands are received from the user phone number the board will send acknowledgement as per the commands.
4.) After that it will send the router’s status once it has rebooted and is operational again.
Mentioned below are a few commands which can be sent from the configured mobile number to the router device. Below two commands are One for rebooting the router device and another to get the uptime.
1) {"device":["passkey","API key"],"command":"reboot","arguments":"hardware"}
2) {"device":["passkey ","API key"],"command":"uptime"}
Loop back IP settings:
The loopback IP address, commonly represented as 127.0.0.1, is a special address used for testing network connectivity on a local machine.
It allows a device to send network messages to itself without involving external networks, making it useful for troubleshooting and diagnostics.
However, this IP can be changed as per requirement and to do that, Navigating to Setting>>Network configuration>> Loopback IP settings can be changed/updated.
After configuring all the required information, click on save.
Flow Offloading:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable Flow Offloading | Enable/Disable
(Disable by default) |
Hardware Flow Offloading: If supported by your device, enabling flow offloading can significantly increase throughput by reducing the CPU load.
Software Flow Offloading: Even without specialized hardware, software-based flow offloading can help optimize network traffic processing. |
2 | SMP IRQ Affinity | Enable/Disable
(Disable by default) |
SMP IRQ Affinity: When enabled, this setting can bind specific IRQs to specific CPU cores, which can optimize the handling of interrupts and improve overall system performance. |
After configuring all the required information, click on save.
3.3 Multi-WAN
As shown below, this section has 4 categories,
Status
General settings
Failover
Load Balancing
In ‘Status’ tab user can see the active network connections on the device as shown above.
General Settings:
In general settings, select any one option from the drop-down menu which you wish to imply and click on save.
Failover
Load Balancing
Click on save and update.
Failover:
NOTE: Please verify that the name to be added is located in the interface section of the status tab.
EDIT:
The specifications details are below.
SN | Field name | Sample value | Description |
1 | Priority | Ex: 5 | Setting a priority of 1 means this connection has the highest priority and will be used before any others with a higher priority number. |
2 | Select Track IP Numbers | 2 | In this dropdown the user needs to select the track number for the Ips. This specifies the number of IP addresses that will be used for tracking the status of the connection. |
3 | TrackIP1 | 8.8.8.8 | The system will ping this IPV4 IP address to check if the connection is up and working. You can even add any whitelisted IP. |
4 | TrackIP2 | 8.8.4.4 | The system will ping this IPV4 IP address to check if the connection is up and working. You can even add any whitelisted IP. |
5 | Reliability | 1 | If reliability is set to 1, it might mean the connection is considered reliable if it successfully pings at least one of the tracked IP addresses. |
6 | Count | 1 | Setting Count to 1 means the device will send one ping to each IP address to check for connectivity. |
7 | Up | 3 | If set to 3, the connection will be considered "up" only if all three pings are successful. |
8 | Down | 3 | If set to 3, the connection will be considered "down" if all three pings fail. |
Click on save and update tab.
Load Balancing:
Load balancing is a network management technique used to distribute traffic across multiple network connections or servers to optimize resource use, maximize throughput, minimize response time, and ensure reliability.
Task: Distributes network traffic evenly across multiple connections (e.g., multiple WAN links) or servers.
Purpose: This ensures that no single connection or server is overwhelmed with too much traffic, which could lead to congestion and slower performance.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Traffic Distribution Ratio | Ex: 60% | If you have two connections and set one to 60% and the other to 40%, traffic will be distributed accordingly.
The ratio must be the same for CWAN1_0 and CWAN1_1. |
2 | Select Track IP Numbers | 2 | The system will track two IP addresses to determine if the network connection is active and reliable. |
3 | TrackIP1 | 8.8.8.8 | The system will ping this IPV4 IP address to check if the connection is up and working. You can even add any whitelisted IP. |
4 | TrackIP2 | 8.8.4.4 | The system will ping this IPV4 IP address to check if the connection is up and working. You can even add any whitelisted IP. |
5 | Reliability | 1 | With a reliability setting of 1, the connection might be considered reliable if at least one ping is successful. |
6 | Count | 1 | The system will send one ping to each tracked IP to check the connection's status. |
7 | Up | 3 | The system requires 3 successful pings for the connection to be marked as "up." |
8 | Down | 3 | If 3 pings fail, the system will mark the connection as "down," and it may switch to an alternate connection if available. |
Click on save and update tab.
3.4 VPN
VPN stands for Virtual Private Network, it establishes a connection between the system and a remote server, which is owned by a VPN provider.
Creating a point-to-point tunnel that encrypts the personal data, masks the IP address, and allows to block the required website to blocks via firewalls on the internet.
Navigate to settings >= VPN, general settings and you will see all VPN options you wish to use.
There are 6 types of setting available under VPN configuration.
General Settings
- IPSEC
- Open VPN
- Wireguard
- Zerotier
- PPTP
*Refer the image below*
General Settings:
In this page the user must choose which type of VPN connection is required for the device.
The user must select from IPSEC, Open VPN, Wireguard, Zerotier or PPTP based on its requirement.
If required, the user can select all the options.
Click on save after selecting the option based on its requirement.
IPSEC:
IPSEC VPN is used to create a VPN connection between local and remote networks.
To use IPSEC VPN, the user should check that both local and remote routers support IPSEC VPN feature.
In this page the user can add/edit/delete the IPSEC VPN connection for the device.
The user needs to click on the update button once the required configuration is completed.
In IPSEC the user needs to click on edit button to edit the configuration of an existing VPN connection.
Click on update once done with configurations.
The tunnel will show established, showing the connection has been made.
Detailed specifications are below:
SN | Field name | Sample value | Description |
1 | IPSEC | Site to Site VPN | In this dropdown the user should select the IPSEC connection type. |
2 | IPSEC Role | Client/Server | In this dropdown box the user needs to select the IPSEC role. The device is acting as a client in the VPN setup (in this example). |
3 | Connection Type | Tunnel | In this dropdown the user needs to select the connection type. The user should select on the connection enable check box. |
4 | Connection mode | Route/add/start/trap | In this drop down list the user should select the mode for the connection. In this example start is selected which means the VPN connection is initiated automatically. |
5 | Remote Server IP | ******** | The IP address of the remote VPN server. |
6 | Local ID | 3.3.3.3 | The user needs to set the local id. It is the identification for the local VPN client. |
7 | No. of local subnets | 1 | In this dropdown the user needs to select how many subnets will be connected. |
8 | Local Subnet 1 | 172.16.31.25/32 | In this text box the user needs to put the specific local subnet included in the VPN. |
9 | Remote id | 1.1.1.1 | In this text box the user needs to put the id of the remote connection. It is the identification for the remote VPN server. |
10 | No of remote subnet | 1 | In this dropdown the user needs to select how many subnets it will be connected remotely. |
11 | Remote subnet | 10.1.1.0/24 | In this text box the user needs to put the address of the remote subnet. The specific remote subnet included in the VPN. |
12 | Key exchange | Ikev1 | In this dropdown the user should select the which key exchange version to be selected. |
13 | Aggressive | Yes/No | In this dropdown the user should select either yes or no. |
14 | IKE Lifetime (In Seconds) | 86400 | The lifetime of the IKE phase in seconds (1 day). |
15 | Lifetime (in seconds) | 28800 | The lifetime of the IPsec SA (Security Association) in seconds (8 hours). |
16 | Enable DPD Detection | 1
0 |
Indicates whether Dead Peer Detection is enabled to detect a lost connection. Enable this option as per server-side settings. |
17 | Time Interval (In Seconds) | 60 | This option is available only if DPD Detection is enabled. The time interval is the interval for DPD checks. |
18 | Action | Restart/clear/hold/
trap/start |
Restart: Action to take when DPD detects a lost connection (restart the connection). Select as per server-side setting. |
19 | Authentication Method | PSK | PSK: Pre-shared key is used for authentication. Select this option for authentication as per sever side setting. |
20 | Multiple Secrets | 1/0 | Indicates whether multiple PSK secrets are used. Enable only if required. |
21 | PSK Value | ****** | Pre-shared key value (masked for security). |
Proposal settings Phase I | |||
22 | Encryption Algorithm | AES 128
AES 192 AES 256 3DES |
AES 256: Encryption algorithm for Phase I. Select as per server-side configuration. Both server and client should have same configuration. |
23 | Authentication Phase I | SHA1
MD5 SHA 256 SHA 384 SHA 512 |
SHA 512: Authentication algorithm for Phase I.
Select as per server-side configuration. Both server and client should have same configuration. |
24 | DH Group | MODP768(group1)
MODP1024(group2) MODP1536(group5) MODP2048(group14) MODP3072(group15) MODP4096(group16) |
MODP2048(group14): Diffie-Hellman group for key exchange.
Select as per server-side configuration. Both server and client should have same configuration. |
Proposal settings Phase II | |||
25 | Hash Algorithm | AES 128
AES 192 AES 256 3DES |
AES 256: Encryption algorithm for Phase II. Select as per server-side configuration. Both server and client should have same configuration. |
26 | Authentication Phase II | SHA1
MD5 SHA 256 SHA 384 SHA 512 |
SHA 512: Authentication algorithm for Phase II.
Select as per server-side configuration. Both server and client should have same configuration. |
27 | PFS Group | MODP768(group1)
MODP1024(group2) MODP1536(group5) MODP2048(group14) MODP3072(group15) MODP4096(group16) |
MODP2048(group14): Perfect Forward Secrecy group.
Select as per server-side configuration. Both server and client should have same configuration. |
For detailed configuration of IPSEC, click the below url.
https://wiki.silbonetworks.com/index.php/Main_Page
Open VPN:
To use the VPN feature, the user should enable OpenVPN Server on the router, and install and run VPN client software on the remote device.
The user needs to “upload” the respective certificate from a valid path and then click on the “Update.”
Only the TAP connection needs a bridge. The tun connection does not require a bridge. Here we have established a TUN connection.
By clicking on the enable/disable button, the user can start/stop the VPN connection.
VPN TUN has been established.
Same way VPN TAP can also be established with the help of bridging.
WireGuard:
WireGuard is simple, fast, lean, and modern VPN that utilizes secure and trusted cryptography.
Click on “Edit” to start configurations as needed.
EDIT:
Specification details are given below:
SN | Field name | Sample value | Description |
1 | Wireguard Role | Client/Server | In this dropdown box the user needs to select the wireguard role. |
2 | WireGuard Tunnel Over | IPV4/IPV6 | IPV4: Use this if your network and endpoint (WireGuard server) support only IPv4.
IPV6: Use this if your network and endpoint support IPv6. |
3 | Enable Failover | Enable/Disable | This option allows the VPN connection to automatically switch to a backup connection if the primary connection fails. |
4 | Enable IPV4 | Enable/Disable | This enables IPv4 traffic to be routed through the WireGuard tunnel. |
5 | Enable IPV6 | Enable/Disable | Enable this if your network and the destination support IPv6. |
6 | Listen Port | 51820 | This is the default port that WireGuard uses to listen for incoming connections. |
7 | Endpoint Host port | 51820 | This is the port on the WireGuard server that the client will connect to. |
8 | Peer Publickey | ***** | This is the public key of the WireGuard server that the client uses to establish a secure connection. |
9 | Enable Default Route | Enable/Disable | Enable this if you want all network traffic (not just specific routes) to be routed through the WireGuard VPN. |
Save and update the page after configuration has been done.
Zerotier:
Go to ZeroTier Central and sign up for a free account. In ZeroTier Central, click on "Create a Network". This will generate a unique 16-digit network ID for your new network.
Go to settings => VPN, in general settings, enable ZeroTier and save.
Copy and paste the unique 16-digit network ID in the edit section.
Click on the save button after the required configuration.
SN | Field name | Sample value | Description |
1 | NetworkID | Ad2769hfkw2345f4 | In this dropdown box the user needs to paste the unique 16-digit network id. |
2 | Listen Port | 9993 | Default |
3.5 Firewall
A firewall is a layer of security between the network and the Internet.
Since a router is the main connection from a network to the Internet, the firewall function is merged into this device.
Every network should have a firewall to protect its privacy.
To configure a Firewall, navigate to settings <= firewall,
There are 6 types of setting available under firewall.
- General Settings
- Port forwards
- Traffic Rules
- SNAT traffic Rules
- Parental Control
- Zone Forwarding
General Settings:
General settings are subdivided into 2 parts,
1.) General settings
In general settings, the settings that are made are default settings and can be changed according to user’s preference.
Specification details are below:
SN | Field Name | Sample Value | Description |
1 | Enable SYN-flood protection | Enabled | This is enabled by default; setting can be changed if required. |
2 | Disable IPV6 | Disabled | This is enabled by default; setting can be changed if required. |
3 | Drop invalid packets | Disabled | This is enabled by default; setting can be changed if required. |
4 | TCP SYN Cookies | Disabled | This is enabled by default; setting can be changed if required. |
5 | Input | Reject/Accept | By default, the setting is ‘Reject’ but this needs to be changed to ‘Accept’ compulsory. |
6 | Output | Reject/Accept | By default, the setting is ‘Reject’ but this needs to be changed to ‘Accept’ compulsory. |
7 | Forward | Reject/Accept | By default, the setting is ‘Reject’ but this needs to be changed to ‘Accept’ compulsory. |
2.) Zone settings
In zone settings, there’s an option to add “New Zone”, according to user’s requirement.
Port Forwards:
Port forwarding is a feature in a router or gateway that allows external devices to access services on a private network.
It maps an external port on the router to an internal IP address and port on the local network, enabling applications such as gaming servers, web servers, or remote desktop connections to be accessed from outside the network.
This helps in directing incoming traffic to the correct device within a local network based on the port number, enhancing connectivity and accessibility.
EDIT:
Click on the save button after the required configuration.
Specification details are given below:
SN | Field name | Sample value | Description |
1 | Name | Example: Web_Server_Forward
|
Field must not be empty. Provide a name for the rule to easily identify it. |
2 | Protocol | Example: TCP+UDP
|
Select the protocol for the rule.
Options typically include TCP+UDP, TCP, UDP, ICMP, Custom. |
3 | Source zone | Example: SW_LAN
|
Select the source zone where the traffic is originating from. Options typically include EWAN2,SW_LAN,CWAN1,CWAN1_0,CWAN1_1,VPN |
4 | Source MAC address [optional] | Example: any
|
any: Leave as any if you don't want to specify a MAC address.
|
5 | Source IP address[optional] | Example: Leave blank if not needed. | Optionally specify an IP address or range. |
6 | Source port | Example: 80, 443 (if matching traffic for web server ports)
|
Specify the source port or port range. |
7 | Destination zone | Example: SW_LAN
|
Select the destination zone where the traffic is heading to. |
8 | Destination IP address | Leave blank if not needed. | Optionally specify the destination IP address or range. |
9 | Destination port | Example: 80 (if redirecting to a web server port)
|
Specify the destination port or port range. |
Traffic Rule:
"Traffic rules" refer to the policies and regulations that govern the flow of data packets within a network.
To allow new traffic, click on “Add and Edit” in “New Traffic Rule”.
EDIT:
Specification details are below:
SN | Field name | Sample value | Description |
1 | Name | Example: Allow_HTTP_and_HTTPS | Field must not be empty: Provide a descriptive name for the traffic rule. |
2 | Restrict to Address Family | 1. Options: IPv4, IPv6
2. Example: IPv4 if dealing with typical internet traffic. |
Select the address family to generate iptables rules for. |
3 | Protocol | Example: TCP+UDP | TCP+UDP: Match incoming traffic using the given protocol. |
4 | Match ICMP Type | Example: any | Match all ICMP types if set to any. Specific types can be chosen if needed. |
5 | Source Zone | Example: LAN | Specifies the traffic source zone. |
6 | Enable DDoS Prevention | Example: ‘Checked’ if you want to enable DDoS prevention measures | Enable or disable Distributed Denial of Service (DDoS) prevention. |
7 | Limit | Example: 10/minute to limit matches to 10 times per minute. | Maximum average matching rate; specified as a number, with an optional /second, /minute, /hour, or /day suffix. |
8 | Limit Burst | Defines how many packets or connections can exceed the rate limit before the limiting mechanism kicks in. | |
9 | Source MAC Address | Example: any | any: Match traffic from any MAC address or specify a particular MAC address. |
10 | Source Address | Example: 192.168.1.0/24 | Match incoming traffic from the specified source IP address or range. |
11 | Source Port | Example: any if all source ports should be matched | any: Match incoming traffic from the specified source port or port range. |
12 | Destination Zone | Example: WAN | Specifies the traffic destination zone. |
13 | Destination address | Options: Any, or a specific IP address/subnet. | The IP address or range to which the incoming traffic is directed. |
14 | Destination port | Options: Any, or a specific port/port range. | Used to allow or block traffic to specific services, like permitting only HTTP (port 80) traffic. |
15 | Action | Example: ACCEPT | Options: ACCEPT, DROP, REJECT. Specify the action to take for matched traffic. |
16 | Extra arguments | Example: --log-prefix "Blocked: " to add a log prefix to log messages for this rule. | Passes additional arguments to iptables. Use with care as it can significantly alter rule behaviour. |
Click on save once configured.
SNAT Traffic Rule:
For configuring SNAT (Source Network Address Translation) traffic rules, you can control how outbound traffic from your local network is translated to a different IP address as it exits the network.
To add new source NAT,
Click on “ADD” in “New Source NAT:”
EDIT:
Specification details are below:
SN | Field name | Sample value | Description |
1 | Name | Example: SNAT_WAN_to_LAN | Field must not be empty: Provide a unique and descriptive name for the SNAT rule. |
2 | Protocol | Example: TCP+UDP | TCP+UDP: Select the protocols that the SNAT rule will apply to. |
3 | Source Zone | Example: wan | wan: Specifies the source zone from which the traffic originates. |
4 | Source IP Address | Example: any or a specific range like 192.168.1.0/24 | -- please choose --: Specify the source IP address or range. Leave empty if the rule applies to any source IP. |
5 | Source Port | Example: any | any: Specify the source port or port range from which the traffic originates. |
6 | Destination Zone | Example: lan | lan: Specifies the destination zone to which the traffic is directed. |
7 | Destination IP Address | Example: any or a specific IP like 192.168.1.100 | -- please choose --: Specify the destination IP address or range. Leave empty if the rule applies to any destination IP. |
8 | Destination port | Example: any | any: Specify the destination port or port range to which the traffic is directed. |
9 | SNAT IP Address | Example: 203.0.113.5 (an external IP address) | -- please choose --: Specify the IP address to which the source IP should be translated. |
10 | SNAT Port | Example: Leave empty if not needed, or specify a port like ‘12345’ | Optionally, rewrite matched traffic to a specific source port. Leave empty to only rewrite the IP address. |
11 | Extra Arguments | Example: --log-prefix "SNAT_traffic: " (to add a log prefix to log messages for this rule) | Pass additional arguments to iptables. Use with care as it can significantly alter rule behaviour. |
Click on save once configured.
Parental Control:
For configuring parental control rules, you want to set restrictions based on time, source, and destination zones, as well as specific devices.
To add parental control in firewall,
Click on “Add and Edit” in “New parental control:” field.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Example: Parental_Control_Sunday | Field must not be empty: Provide a unique and descriptive name for the parental control rule. |
2 | Proto | all | all: This specifies that the rule will apply to all protocols. |
3 | Source Zone | Example: lan | Field must not be empty: Please look at Firewall->Zone Settings to find zone names. |
4 | Destination Zone | Example: wan | Field must not be empty: Please look at Firewall->Zone Settings to find zone names. |
5 | Source MAC Address | Example: 00:1A:2B:3C:4D:5E | Field: Enter the MAC address of the device you want to apply the parental control rule to. This is useful for restricting specific devices. |
6 | Target | Example: Reject | Accept: This specifies the action to take. For parental controls, you might want to use ‘Reject’ or ‘Drop’ to block traffic. |
7 | Weekdays | Example: Sunday | Sunday: Specify the days of the week when the rule should be active. |
8 | Month Days | Example: All | All: Specify the days of the month when the rule should be active. |
9 | Start Time (hh:mm:ss) | Example: 18:00:00 (6:00 PM) | Field must not be empty: Specify the start time when the rule should begin to apply. |
10 | Stop Time (hh:mm:ss) | Example: 22:00:00 (10:00 PM) | Field must not be empty: Specify the stop time when the rule should end. |
Click on save once configured.
Zone Forwarding:
Zone forwarding in network configuration allows traffic to be directed from one zone to another.
To ADD new zone,
Click on “Add” in “New Zone Forward:” field.
*Refer the image below*
EDIT:
Specification details are below:
SN | Field Name | Sample Value | Description |
1 | Source Zone | Example options: CWAN (1,2,3), EWAN (1,2,3), VPN & custom. | --please choose--: Select the source zone from which the traffic originates. |
2 | Destination Zone | Example options: SW_LAN, EWAN3 & custom. | --please choose--: Select the destination zone to which the traffic is directed. |
Click on save once configured.
3.6 SIM Switch
In this page the user needs to configure the Sim for the given device.
*Refer the image below*
The user needs to select from the drop-down menu on which basis the sim needs to be switched.
Once the user selects on “signal strength” then the parameters related to signal strength will pop up and the user needs to configure the parameters based on the requirement.
Threshold RSRP:
This Needs to be set appropriately. Incorrect setting may cause unnecessary SIM switching. (In General, a BAD RSRP value range is -140 to -115 and FAIR RSRP value range is -115 to -105).
Threshold SINR:
This Needs to be set appropriately. Incorrect setting may cause unnecessary SIM switching. (In General, a BAD SNR value range is -20 to 0 and FAIR SNR value range is 0 to 13).
Once the user selects on “Data Limit” then the parameters related to Data Limit will pop up and the user needs to configure the parameters based on the requirement.
Specification details are given below:
SN | Field name | Sample value | Description |
1 | SIM Switch Based on | Data Limit | The user needs to select from the drop-down menu on what basis the sim needs to be switched. |
2 | SIM 1 Data Usage Limit (In MB) | 1000 | The user needs to set the limit for the data usage for SIM 1. |
3 | SIM 2 Data Usage Limit (In MB) | 1000 | The user needs to set the limit for the data usage for SIM 2. |
4 | Periodicity | Daily | The user needs to set the pattern/frequency to switch the sims. |
5 | Day Of Month | For Ex: 16 | The user needs to set the day for switching the sim. |
After configuring all the required information, the user should click on the save.
3.7 Traffic Shaping
Traffic shaping also known as SQM (Smart Queue Management).
The combination of the correct interface, queueing discipline, setup script, and accurate
upload/download speed value allows SQM to effectively reduce latency, manage congestion, and
improve overall network performance.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Interface | Options:
eth0.1 eth0.5 ra0 (WiFi 2.4 GHz) wlan0 (WiFi 5 GHz) eth1 |
You choose the interface corresponding to the connection you want to manage, whether it's a wired connection (eth0.x, eth1) or a wireless one (ra0, wlan0). |
2 | Queueing Discipline | Options:
Cake fq_code |
You select the appropriate qdisc based on your needs; Cake is often preferred for its advanced features and ease of configuration. |
3 | Queue Setup Script | Options:
piece_of_cake.qos layer_Cake.qos |
Choose the script that best suits your network environment; layer_Cake.qos provides more features, while piece_of_cake.qos is easier to use. |
4 | Upload Speed (kbps) | 10000 kbps | This field specifies the maximum upload speed in kilobits per second that your connection can handle. |
5 | Download Speed (kbps) | 85000 kbps | This field specifies the maximum download speed in kilobits per second that your connection can handle. |
Click on save once configured.
3.8 Loopback Rule
In this page the user can configure the port where he wants to forward the traffic to. Here the user can add/edit/delete different ports as per the requirement.
The user should click on ‘add’ and then ‘edit’ to do the required changes in the port and enter the valid information in each section to configure the port for forwarding.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Example: loopback | Provide a descriptive name for the rule. |
2 | Protocol | Example: TCP+UDP | TCP+UDP: Select the protocols that the rule will apply to. |
3 | Source IP Address [Optional] | Example: any or a specific IP range like 192.168.1.0/24 | Optionally specify the source IP address or range. Leave empty if the rule should apply to any source IP. |
4 | Source Port [Optional] | Example: any | any: Specify the source port or port range from which the traffic originates. any allows traffic from all ports. |
5 | Destination IP Address | Example: 172.16.31.25 | Only match incoming traffic with this Destination IP or range. Typically, this is 127.0.0.1. |
6 | Destination Port | Example: 81 | Only match incoming traffic originating with the given destination port or port range on the client host. |
7 | Action | Example: DNAT | This specifies the action to take either DNAT or SNAT. |
8 | Internal IP Address | Example: 192.168.1.100 | Field must not be empty: Specify the internal IP address to which the traffic should be redirected. |
9 | Internal Port | Example: 81 | Redirect matched incoming traffic to the given port on the internal host. |
Once the user is done with the required configurations, user should click save button and then click on update to save the changes.
3.9 VRRP
VRRP (Virtual Router Redundancy Protocol) is used to ensure high availability for IP routing by allowing multiple routers to work together to present the illusion of a single virtual router to the hosts on a network.
In General Settings,
Click on ‘Enable VRRP’ and save.
In VRRP section,
Give a name and ‘Add’ device.
Click on ‘Edit’ to make changes.
Click on ‘Delete’ if particular instance not required.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Role | 1. Master
2. Backup |
Choose Master for the primary router that should handle the traffic under normal circumstances.
Choose Backup for a secondary router that will take over if the master fails. |
2 | Virtual ID | Ex: 0 | The value can range from 0 to 255.
Ensure all routers in the same VRRP group share the same Virtual ID. |
3 | Priority | Ex: 100 | For the Master role, use the highest priority, typically above 100.
For the Backup role, set a lower priority number, usually below the master's priority. |
4 | Interface | SW_LAN | This is the network interface on which VRRP operates. |
5 | Source IP | Ex: 192.168.10.1 | This is the IP address used as the source in VRRP advertisements. |
6 | Peer IP | Ex: 192.168.10.10 | This is the IP address of the other VRRP peer (usually the backup router). It helps the routers identify each other. |
7 | Virtual IP Address | 192.168.10.100/24 | The virtual IP should be an unused address within the subnet, such as 192.168.10.100/24, ensuring it's consistent across all VRRP routers. |
8 | Enable Authentication | Enable/Disable | Enable this if you want to secure your VRRP communications. |
9 | Password | ********* | It ensures that only routers with the correct password can join the VRRP group. |
Save and update once changes have been made.
3.10 Remote Monitoring
In this page the user can select which device needs to be monitored remotely.
Once the user selects the type of RMS click on save.
NMS:
In this page the user should type the server IP or domain name in the URL then click on save.
Click on upload and start (Once key is uploaded and this option is clicked, NMS automatically starts, and this router device gets registered with the NMS server provided).
TR_069:
To enable the TR_069 the user needs to click on the enable check box.
Once the user clicks on the check box of enable it will display all the required filed to configured.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable TR-069 | Enable/Disable | When enabled, the device can be remotely managed and configured by a service provider using a TR-069 server. |
2 | Periodic Enable | Enable/Disable | It ensures that the device regularly checks in with the management server for updates, configuration changes, or status reports. |
3 | Accept Server Request | Enable/Disable | By accepting server requests, the device can be managed in real-time, allowing the server to push updates, configurations, or commands to the device. |
4 | Serving Interval | 300 | A value of 300 seconds means the device will check in with the ACS (auto-configuration servers) every 5 minutes. |
5 | Interface | This can be something like eth0 or wan. | This specifies the network interface used for TR-069 communication. |
6 | Username | Example: User | The username used to authenticate with the ACS. |
7 | Password | •••• | The password used to authenticate with the ACS. |
8 | URL | https://167.71.232.131 | The URL of the ACS. This is where the CPE (customer-premises equipment) will send its requests and where it will receive configurations and updates from. |
The user should fill all the required fields and click on the save button.
3.11 Tunnel
Tunnels are a method of transporting data across a network using protocols which are not supported by that network.
In General Settings, there are 2 tunnels.
1.) GRE Tunnel
2.) IPIP Tunnel
Enable either of them and click on save.
GRE Tunnel:
A GRE (Generic Routing Encapsulation) tunnel configuration involves setting up a virtual point-to-point connection between two endpoints over an IP network.
Here the user can add/edit/delete the details of the tunnel.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Tunnel name | Example: GRETunnel | GRETunnel: The name of the GRE tunnel. |
2 | Local external IP | Example: 10.1.1.66 | The IP address of the local endpoint that will initiate the GRE tunnel. |
3 | Remote external IP | Example: 10.1.1.40 | The IP address of the remote endpoint that will terminate the GRE tunnel. |
4 | Peer tunnel IP | Example: 10.1.1.4 | The IP address of the peer's tunnel interface. |
5 | Local tunnel IP | Example: 10.1.1.6 | The IP address of the local tunnel interface. |
6 | Local tunnel net mask | Example: 255.255.255.0 | The subnet mask of the local tunnel interface. |
7 | Remote IP | Example: 192.168.10.0/24 | The remote network that is reachable through the GRE tunnel. |
8 | Enable Tunnel Link | Check to enable | Enable or disable the GRE tunnel link. |
9 | Interface type | Example: EWAN2 | EWAN2: The type of network interface used for the GRE tunnel. |
10 | MTU | Example: 1476 | 1476: Maximum Transmission Unit size for the GRE tunnel. |
11 | TTL | Example: 64 | 64: Time To Live value for the packets within the GRE tunnel. |
12 | Tunnel key | Example: 12345678 | 12345678: A unique key used to identify the GRE tunnel. |
13 | Enable keep alive | Check to enable | Enable or disable the keep-alive feature to monitor the tunnel's status. |
14 | Keep alive interval | Example: 10 | 10: Interval in seconds for the keep-alive packets. |
Once the required update is done then click on update to save the changes.
IPIP Tunnel:
An IPIP (IP-in-IP) tunnel is a simple tunnelling protocol used to encapsulate IP packets within IP packets. This is like GRE but without additional features such as keying and type fields.
Here the user can add/edit/delete the details of the tunnel.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Tunnel name | Example: IPIPTunnel | IPIPTunnel: The name of the IPIP tunnel. |
2 | Local external IP | Example: 10.1.1.66 | The IP address of the local endpoint that will initiate the IPIP tunnel. |
3 | Remote external IP | Example: 10.1.1.40 | The IP address of the remote endpoint that will terminate the IPIP tunnel. |
4 | Peer tunnel IP | Example: 10.1.1.4 | The IP address of the peer's tunnel interface. |
5 | Local tunnel IP | Example: 10.1.1.6 | The IP address of the local tunnel interface. |
6 | Local tunnel net mask | Example: 255.255.255.0 | The subnet mask of the local tunnel interface. |
7 | Remote IP | Example: 192.168.10.0/24 | The remote network that is reachable through the IPIP tunnel. |
8 | Enable Tunnel Link | Check to enable | Enable or disable the IPIP tunnel link. |
9 | Interface type | Example: EWAN2 | EWAN2: The type of network interface used for the IPIP tunnel. |
10 | MTU | Example: 1476 | 1476: Maximum Transmission Unit size for the IPIP tunnel. |
11 | TTL | Example: 64 | 64: Time To Live value for the packets within the IPIP tunnel. |
12 | Tunnel key | Example: 12345678 | Although typically not used in IPIP, this field might be included for compatibility with certain configurations. |
13 | Enable keep alive | Check to enable | Enable or disable the keep-alive feature to monitor the tunnel's status. |
14 | Keep alive interval | Example: 10 | 10: Interval in seconds for the keep-alive packets. |
Once the required update is done then click on update to save the changes.
4. Features
In this module the user can see all the features that the router has.
This module includes the below features.
- Wifi MacID Filtering
- Mac Address Binding
- URL Filtering
- Web Server
- SNMP Agent Configuration
- Others
4.1 Wi-Fi MacID filtering
Wireless MAC ID Filtering allows you to control which devices can connect to your wireless network based on their MAC (Media Access Control) addresses. This can help enhance security by allowing only specified devices to access the network.
It is further divided into 2 categories,
WIFI 2.4G AP
WIFI 2.4G AP Guest
Before adding the MacIDs the user needs to select the mode from the dropdown menu.
In ‘Change Mode’ select one option,
Blacklist
In blacklist mode, you specify which MAC addresses are not allowed to connect to the wireless network. Devices not on the blacklist will be able to connect.
Whitelist
In whitelist mode, you specify which MAC addresses are allowed to connect to the wireless network. Devices not on the whitelist will be blocked.
To Add the MacID the user needs to click on Add New option.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Status | Enable/Disable | Enable or disable the MAC ID filtering. |
2 | MAC ID | Example: e8:6f:38:1a:f2:61 | The MAC address of the device to be whitelisted or blocklisted. |
3 | Network Name | Example: WIFI 2.4G AP or Wi-Fi 2.4G AP Guest. | The network to apply the MAC ID filtering. |
Once the required MAC ID and Network Name is configured the user needs to click on the save button to add the details.
The user needs to click on the edit button to do modifications on the pre-existing configuration.
Once the required MACID / Network Name is modified the user needs to click on the update button to reflect the changed value in the application.
4.2 Mac Address Binding
MAC address binding is a configuration that binds a specific MAC address to a specific IP address.
To add multiple devices, click on ‘Add’.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Device Name | Ex: Mac1 | A user-defined name for the binding configuration. |
2 | MAC Address | Ex: 48:9e:bd:da:45:91 | The unique identifier for the network interface of the device to which the IP address will be bound. |
3 | IP Address | Ex: 192.168.10.55 | The IP address that will be consistently assigned to the device with the specified MAC address. |
By applying this configuration, the DHCP server will always assign the IP address 192.168.10.55 to the device with the MAC address 48:9e:bd:da:45:91, ensuring consistency and stability in network addressing for that device.
- Once the user modifies the MAC address /IP Address then click on the save button to save the changes done.
- The user can click on the deleted button to delete an existing configured device.
- Post all the changes the user needs to click on the update to reflect all the changes in the application.
Click on save tab once changes have been made.
4.3 URL Filtering
In this submodule the user should provide the URL which needs to be blocked for the device. By implementing URL filtering with the specified URL, you can control and restrict access to certain websites, thereby improving network security and managing user access.
In ‘Change Mode’ select one option,
Blacklist: In blacklist mode, you specify which MAC addresses are not allowed to connect to the wireless network. Devices not on the blacklist will be able to connect.
Whitelist: In whitelist mode, you specify which MAC addresses are allowed to connect to the wireless network. Devices not on the whitelist will be blocked.
To add the new URL for blocking, click on the Add New button.
Once the user clicks on the Add New button a new pop will appear in that page write the URL and click on the save.
The user can select the status of that URL while defining the URL.
To edit / delete the existing URL the user needs to click on the edit /deleted button respectively.
Click on “save” after the changes are done as per the need.
4.4 Web Server
This configuration will allow your device to serve web traffic securely over HTTPS, keep its system time synchronized, and ensure that all HTTP traffic is redirected to HTTPS for better security.
If any of the configuration is changed, please reboot the board.
Specification details are given below.
SN | Field Name | Sample Value | Description |
1 | Enable HTTP | HTTP Port: 80
Enable or disable the HTTP server. |
Port 80 is the default port for HTTP traffic. It is used to serve web pages over an unencrypted connection. |
2 | Enable HTTPS | HTTPS Port: 443
Enable or disable the HTTPS server. |
Port 443 is the default port for HTTPS traffic. It is used to serve web pages over an encrypted connection. |
3 | Redirect HTTPS | Option to redirect HTTP traffic to HTTPS. | When enabled, all HTTP requests will be automatically redirected to the HTTPS port to ensure secure communication. |
4 | Session Timeout (in secs) | Ex: 60secs | This setting controls how long a user session remains active without interaction before the server automatically logs the user out. |
5 | RFC1918 Filter | Enable/Disable | When enabled, this filter can block traffic from private IP ranges (e.g., 192.168.x.x, 10.x.x.x) from being routed through the public internet, enhancing network security. |
6 | Enable NTP Sync | Enable or disable NTP synchronization. | Synchronizes the device’s system clock with an external NTP server to maintain accurate time. |
7 | NTP Server | 0.openwrt.pool.ntp.org | The address of the NTP server used for time synchronization. The openwrt.pool.ntp.org server is a public NTP server pool. |
8 | NTP Sync Interval (In Minutes) | 15 | The interval at which the device will sync its clock with the NTP server, set to every 15 minutes in this case. |
4.5 SNMP Agent Configuration
The SNMP (Simple Network Management Protocol) Agent Configuration is essential for monitoring and managing network devices, such as routers, from a central management system.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable SNMP Service | Enable/Disable | Enable this if you want the device to be accessible for SNMP-based monitoring and management. |
2 | IP Family | IPV4 | Specifies that SNMP service will operate over IPv4. |
3 | Port | 161 | 161 is the default and should be used unless there is a specific need to use a different port. |
4 | System OID | 1.3.6.1.4.1.38151 | This unique identifier represents the device in the SNMP management system. |
5 | Name | Invendis Router | The name used to identify the device in the SNMP management system. |
6 | Contact | Invendis@invendis.co | The email address of the person responsible for the device, used for administrative contact. |
7 | Location | Bangalore | The physical location of the device. |
8 | SNMP Version | Version-1,
Version-2, Version-3 |
Version-1: Basic and outdated, offering no security.
Version-2: An improvement over Version-1 with better performance and some security features. Version-3: The most secure, offering authentication and encryption (AuthPriv). |
9 | Security (for SNMP Version-3) | NoAuthNoPriv
AuthNoPriv AuthPriv |
No Authentication, No Privacy
Authentication, No Privacy Authentication and Privacy |
10 | Username | Ex: admin | The username used for SNMP authentication. |
11 | Authentication Password | ******* | This password is used to authenticate the SNMP user. |
12 | Privacy Password | ******* | This password is used to encrypt SNMP messages. |
13 | Download MIB File | Download | Click this to download the MIB file associated with the device’s SNMP configuration. |
Click on save tab to save changes.
4.6 Others
In this page the user will get to do all the other miscellaneous configuration with respect to the device based on the required parameters. Each utility serves a specific purpose, providing various functionalities for managing and troubleshooting network configurations and statuses.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Set Date | Date and time fields (day, month, year, hour, minute, second) | Sets the system date and time to the specified values. |
2 | Get Date | System | Retrieves and displays the current system date and time. |
3 | IP Rule Show | Command ‘Get’ | Displays the current IP rules configured on the device. |
4 | Advanced Static Routes | Command ‘Run’ | Used to manually define routing paths for network traffic. |
5 | ipsec status all | Command ‘Get’ | Displays the status of all IPsec connections. |
6 | iPerf3 Client | IP address (e.g., 192.168.10.100) | Runs an iPerf3 client to measure network performance. |
7 | iPerf3 Server | Command ‘Run’ | Runs an iPerf3 server to measure network performance. |
8 | Ping | IP address or domain (e.g., 8.8.8.8) | Sends ICMP echo requests to the specified address to check connectivity. |
9 | traceroute | IP address or domain (e.g., 8.8.8.8) | Traces the route packets take to reach the specified address. |
10 | ReadSIMInfo | SIM1
SIM2 |
Reads and displays information about the SIM card installed in the device. |
11 | NTP Sync | Command ‘Sync’ | Synchronizes the system time with the configured NTP server. |
12 | ReadLogFiles | Log file identifier | Reads and displays the specified log file |
13 | Download Files | File or database identifier | Initiates a download of the specified file or database. |
14 | Restart Power | Command ‘Restart’ | Restarts the power of the device. |
15 | Restart Modem1 | Command ‘Restart’ | Restarts the modem. |
16 | Run AT Command | Enter AT command | Executes the specified AT command on the modem. |
17 | Scan Network operators for modem1 (Takes >3 mins) | Command ‘Scan’ | Initiates a scan for available network operators. |
18 | Network operator list for modem1 (First Perform Scan Network Operators) | Command ‘Show’ | Displays the list of network operators detected in the previous scan. |
19 | Show Board Configuration | Command ‘Show’ | Displays the current board configuration. |
20 | Switch SIM to Secondary (Takes >2 mins) | Command ‘Run’ | Switches the active SIM to the secondary SIM card. |
21 | Send test SMS | Phone number (e.g., +911234567890) message text (e.g., "Hello how are you?") | Sends a test SMS to the specified phone number. |
22 | ReadlatestSMS | Command ‘Read’ | Reads the most recent SMS received by the device. |
23 | Enable ssh (Admin) | Command ‘Run’ | Enables SSH access for the admin user. |
24 | Disable ssh (Admin) | Command ‘Run’ | Disables SSH access for the admin user. |
25 | Output | Any value | Displays output for all the above actions. |
5.Maintenance
In this module the user can configure/upgrade/modify the settings related to system, password, firmware and monitoring.
It includes below 8 submodules.
- General
- Scheduled Tasks
- Password
- Reboot
- Import and Export config
- Firmware upgrade
- Monitor Application
- Router Software Install/Uninstall
5.1 General
Here you can configure the basic aspects of router like its hostname or the time zone.
It is further sub-divided into,
1.) General Settings
2.) Logging
3.) Language and Style
General Settings:
The System Properties section allows you to manage the general settings of your network device, including time settings, logging, hostname, and language preferences.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Local Time | 2024/08/23 09:44:47 | The current local date and time set on the device. |
2 | Hostname | 41B01240016 | The hostname of the device, which is used to identify it on the network. |
3 | Time zone | Asia/Kolkata | The time zone setting of the device, which determines the local time. |
Time Synchronization:
SN | Field Name | Sample Value | Description |
1 | Enable NTP Client | Enable/Disable | When enabled, the device periodically syncs its clock with an external NTP server, ensuring the local time remains accurate. |
2 | Enable NTP Server | Enable/Disable | When enabled, the device acts as an NTP server, allowing other devices on the network to sync their time with it. |
3 | NTP Server Candidates | 0.openwrt.pool.ntp.org
1.openwrt.pool.ntp.org 2.openwrt.pool.ntp.org 3.openwrt.pool.ntp.org |
Provides multiple server options to ensure redundancy and reliability in time synchronization. If one server is unavailable, the device can try another in the list.
You can add or remove any. |
Once the user configures the required details then click on save tab.
Logging:
Here the user can configure the basic aspects of your device related to system.
The system log configuration provided specifies how the device handles and stores log information, including buffer size, external log server details, and log detail levels.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | System log buffer size | Example: 32 kiB | The size of the memory buffer allocated (0-32) for storing system logs before they are either written to a file or sent to an external server. |
2 | External system log server | Example: 0.0.0.0 | The IP address of an external server where logs can be sent. |
3 | External system log server port | Example: 514 | The port used to send logs to the external log server. Port 514 is the default port for syslog. |
4 | Log output level | 1.) Debug
2.) Info 3.) Notice 4.) Warning 5.) Error 6.) Critical 7.) Alert 8.) Emergency |
Debug: Logs all messages, including detailed debugging information. This is the most verbose setting and can be useful for troubleshooting specific issues.
Info: Logs informational messages, which may include normal operational messages. Notice: Logs normal but significant conditions that aren't errors. Warning: Logs warning conditions that indicate potential issues. Error: Logs error conditions that indicate problems. Critical: Logs critical conditions that require immediate attention. Alert: Logs alert conditions that require urgent attention. Emergency: Logs only the most severe conditions that indicate the system is unusable. |
5 | Cron Log level | 1.) Debug
2.) Normal 3.) Warning |
Debug: Use for detailed troubleshooting.
Normal: Use for typical monitoring. Warning: Use to track only issues and errors. |
Time Synchronization:
SN | Field Name | Sample Value | Description |
1 | Enable NTP Client | Enable/Disable | When enabled, the device periodically syncs its clock with an external NTP server, ensuring the local time remains accurate. |
2 | Enable NTP Server | Enable/Disable | When enabled, the device acts as an NTP server, allowing other devices on the network to sync their time with it. |
3 | NTP Server Candidates | 0.openwrt.pool.ntp.org
1.openwrt.pool.ntp.org 2.openwrt.pool.ntp.org 3.openwrt.pool.ntp.org |
Provides multiple server options to ensure redundancy and reliability in time synchronization. If one server is unavailable, the device can try another in the list.
You can add or remove any. |
Once the user configures the required details then click on save tab.
Language and Style:
Here the user can configure the basic aspects of your device related to language.
Time Synchronization:
SN | Field Name | Sample Value | Description |
1 | Enable NTP Client | Enable/Disable | When enabled, the device periodically syncs its clock with an external NTP server, ensuring the local time remains accurate. |
2 | Enable NTP Server | Enable/Disable | When enabled, the device acts as an NTP server, allowing other devices on the network to sync their time with it. |
3 | NTP Server Candidates | 0.openwrt.pool.ntp.org
1.openwrt.pool.ntp.org 2.openwrt.pool.ntp.org 3.openwrt.pool.ntp.org |
Provides multiple server options to ensure redundancy and reliability in time synchronization. If one server is unavailable, the device can try another in the list.
You can add or remove any. |
Once the user configures the required details then click on save tab.
5.2 Scheduled Tasks
This is the system crontab in which scheduled tasks can be defined.
Each asterisk (*) can be replaced with specific values or ranges to schedule the task at a precise time.
*/15 * * * * /root/InterfaceManager/script/TimeSync.sh
- Description: This script is scheduled to run every 15 minutes.
*/2 * * * * /root/InterfaceManager/script/Check_Monitoring.sh
- Description: This script is scheduled to run every 2 minutes.
*/1 * * * * /root/InterfaceManager/script/Update_Analytics_data.sh
- Description: This script is scheduled to run every minute.
*/15 * * * * /root/InterfaceManager/script/IpsecRestart.sh
- Description: This script runs every 15 minutes.
* 1 * * * /root/InterfaceManager/script/vpn/openvpn/openvpnstatus.sh
- Description: This script runs at 1 AM every day.
Summary:
The crontab entries shown define various scripts that are scheduled to run at regular intervals, ranging from every minute to every hour.
The scripts perform tasks like time synchronization, monitoring checks, analytics data updates, SMS file deletion, IPSec status checks, and VPN status checks.
Important Note: After making any changes to the crontab, make sure to save and possibly restart the cron service to apply the changes.
5.3 Password
In this module the user can set the password for the admin credentials.
Note: Password must contain at least one uppercase letter, one digit, one special character, and be at least 8 characters long.
Save the page once you have changed the password.
5.4 Reboot
In this module the user can reboot the device remotely.
First option is to directly reboot the device without enabling the maintenance reboot tab.
Click on “Reboot Now” at the bottom of the screen to start the reboot process.
To start maintenance reboot process first the user needs to fill all the required fields.
Need to select the type of reboot for the device whether it needs to be Hardware or Software reboot.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable Maintenance Reboot | Enable/Disable | Indicates whether the maintenance reboot feature is enabled or not. |
2 | Type | Maintenance Reboot | Specifies the type of reboot being scheduled. |
3 | Reboot Type | Software/Hardware | Hardware: A hardware reboot involves restarting the entire device as if it were powered off and on again.
Software: A software reboot involves restarting the operating system without powering off the hardware. |
4 | Minutes | Example: 59 | The minute at which the reboot should occur (0-59). |
5 | Hours | Example: 22 (10 PM) | The hour at which the reboot should occur (0-23, in 24-hour format). |
6 | Day Of Month | Example: All | Specifies which days of the month the reboot should occur (1-31). "All" means it will occur every day. |
7 | Month | Example: All | Specifies which months the reboot should occur (1-12). "All" means it will occur every month. |
8 | Day Of Week | Example: All | Specifies which days of the week the reboot should occur (0-6, where 0 is Sunday). "All" means it will occur every day of the week. |
5.5 Import and Export
In this section, User can Import & Export Configuration files of the Device.
Click “Export Config” to export device configuration & settings to a text file,
Click “Import Config” to import device configuration & settings from a previously exported text file.
The user needs to select on the “choose file”, upload the required file and click on apply.
5.6 Firmware Upgrade
The user can upgrade with the latest software for the existing firmware.
Click on the flash image and chose the path where the sys-upgrade file is kept and then click on flash image, it will upgrade to the latest software once the reboot is done.
This option will completely reset the device to default settings.
Click on the Retain Config and flash and chose the path where the sys-upgrade file is kept and then click on Retain Config and flash, it will upgrade to the latest software once the reboot is done.
This refers to updating the firmware (flashing) of a device while preserving the current configuration settings.
Click on the Factory Reset for the complete reset of the device.
5.7 Monitor Application
In this section, the monitor application is divided into major 2 configurations which is further sub-divided into 4 editable options,
1.) Modem 1 Local Monitor Application:
2.) Modem 1 Remote Monitor Application:
Modem 1 Local Monitor Application:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable Router Local Ping Check Application | Enable/Disable | Turns on the functionality to perform ping checks on specified IP addresses. |
2 | Time Interval for Check (In minutes) | Example: 10 minutes | Frequency at which the ping checks are performed. |
3 | Select No of IP addresses to ping | Example: 1 | Number of IP addresses that will be pinged. |
4 | IP Address 1 | Example: 8.8.8.8 | The IP address to ping. |
5 | No. of Retries | Example: 5 | Number of times to retry pinging an IP address if the initial ping fails. |
6 | Failure Criteria in (%) | Example: 80% (If 4 out of 5 pings fail, it’s considered a failure) | Percentage of failed pings required to consider the ping check a failure. |
7 | Action On Failure | Options: Restart IPsec, Restart Board, Restart Modem | Action to be taken if the ping check fails according to the criteria. |
8 | Enable Second Level Action | Enable/Disable | Option to enable a secondary action if the primary action fails multiple times. |
9 | Second Level Action Threshold | Example: 2 | Number of failures required to trigger the secondary action. |
10 | Second Level Action | Example: Restart Board (Reboots the entire hardware board) | The action to be taken if the second level action threshold is met. |
Save the details once made necessary changes.
Modem 1 Remote Monitor Application:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable Router Remote Ping Check Application | Enable/Disable | Activates the ping check functionality to monitor router performance. |
2 | Time Interval for Check (In minutes) | Example: 10 minutes | How frequently the ping checks are performed. |
3 | Select No of IP Addresses to Ping | Example: 1 (Please select the appropriate number based on your requirements) | Choose the number of IP addresses to ping. This typically involves selecting from a list or entering multiple addresses. |
4 | No. of Retries | Example: 3 | Number of retries if a ping fails. |
5 | Failure Criteria in (%) | Example: 80% (If 80% of the pings fail, it’s deemed a failure) | Percentage of failed pings required to consider the ping check as failed. |
6 | Action On Failure | Options: Restart IPsec, Restart Board, Restart Modem | The action taken if the ping check fails according to the criteria. |
7 | Enable Second Level Action | Enable/Disable | Option to enable an additional action if the primary action fails. |
8 | Second Level Action Threshold | Example: Specify the number of failures, such as 4 | Number of times the primary action must fail before the secondary action is triggered. |
9 | Second Level Action | Example: Restart Board | The action to be taken if the second level action threshold is met. |
Save the details once made necessary changes.
5.8 Router Software Install/Uninstall
6. Routing
Routing refers to the process of determining the path that data packets take from their source to their destination across networks.
This section is divided into 5 sections,
- Static Routing
- BGP (Border Gateway Protocol)
- OSPF (Open Shortest Path First)
- Dynamic Custom File
- Routing Debug
*Refer the image below for reference*
6.1 Static Routing
In this submodule the user can configure the parameters related to routing of the device like Target address, Networks address etc. Routing configurations allow network packets to be directed between different subnets and networks.
It is further divided into 2 sections,
Static IPV4 Routes
Advanced Static IPV4 Routes
Static IPV4 Routes:
Click on ‘Add’ to add a new interface.
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Interface | Ex: eth0.1 | The network interface to be used for this route. Select the one to use from dropdown. |
2 | Target | Ex: 192.168.20.0 | The destination subnet to which traffic should be routed. |
3 | IPv4 Netmask | 255.255.255.0 | The subnet mask for the target network. |
4 | Metric | 0 | The priority of the route.
Lower values indicate higher priority. |
5 | IPv4 Gateway | Ex: 192.168.10.1 | The gateway IP address to be used for routing traffic to the target subnet. |
6 | Route Type | Unicast | Standard route for individual destination IP addresses.
Custom changes can be made. |
Click on save once configuration changes have been made.
Advanced Static IPV4 Routes:
This is further divided into 2 sections,
Routing Tables
Routing Rules for IPV4
Routing Tables:
Adding a new table in static routing allows you to define specific routes for traffic within a network.
Click on ‘Add’ to add a new Table.
EDIT:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | ID of Table | Ex: 1 | A unique identifier for the routing table. Multiple tables can be used to define different sets of routing rules, providing flexibility in how traffic is managed. |
2 | Name of Table | Ex: Route | A descriptive name for the routing table, making it easier to manage and identify different tables. |
3 | Target | Ex: 192.168.10.0 | Specifies the destination network or IP address that the route is intended for. |
4 | IPv4 Netmask | 255.255.255.0 | Defines the subnet mask for the target network. |
5 | Metric | Ex: 0 | Indicates the priority of the route. A lower metric value means a higher priority. Routes with lower metrics are preferred over those with higher metrics. |
6 | IPv4 Gateway | Ex: 10.1.1.1 | Specifies the next hop or gateway IP address through which the traffic to the target network should be routed. |
7 | Route Type | 1.) Unicast
2.) Custom |
Unicast: Standard route where packets are sent to a single destination IP address.
Custom: Enables advanced routing configurations or specific protocols that might not be covered by default. |
Routing Rules for IPV4:
Click on ‘Add’ to add a new interface.
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Interface | Ex: ra0 | Select the specific network interface on the router through which traffic enters or exits. |
2 | To | Ex: 192.168.10.1 | The destination IP address or network. In this case, 192.168.10.1 is the target IP address for routing traffic. |
3 | IPv4 Netmask | Ex: 255.255.255.192 | Defines the subnet mask, which helps determine the size of the network. |
4 | Table ID | Ex: 1 | Identifies which routing table this rule applies to. |
5 | From | Ex: 192.168.100.1 | Specifies the source IP address or network from which the traffic originates. In this case, the traffic is coming from 192.168.100.1. |
6 | Priority | Ex:20 | Determines the order in which routing rules are evaluated. Lower numbers have higher priority. If two rules conflict, the one with the lower priority number will be applied first. |
7 | Outgoing Interface | 1.) fwmark
2.) iif (Incoming Interface) 3.) oif (Outgoing Interface) 4.) lookup 5.) blackhole 6.) prohibited 7.) unreachable |
1.) This allows you to create rules that apply only to traffic that has been marked in a specific way by the firewall.
2.) This is often used to create rules based on the interface through which traffic is received. 3.) This allows you to control the flow of traffic based on the desired outgoing interface. 4.) It tells the router to check the specific routing table ID mentioned to determine how to route the traffic. 5.) This is used when you want to block traffic without notifying the sender. 6.) Like blackhole but sends an ICMP unreachable message to the sender, indicating that the route is prohibited. 7.) Causes the router to send an ICMP unreachable message to the source IP, notifying that the destination is unreachable. |
6.2 BGP
BGP is crucial for the operation of the internet, allowing routers to exchange information and find the best paths for data to travel across multiple networks globally.
This section is divided into 5 sub sections,
- Status
- General settings
- Instance
- Peers
- Peer Group
The ‘Status’ section will show the status of the connections made.
General Settings:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable BGP | Enable/Disable | This setting is used to turn on BGP functionality on the router. Once enabled, the router can participate in BGP routing, exchange routing information with other BGP peers. |
2 | Enable vty | Enable/Disable | vty refers to the Virtual Terminal lines on a router, which allow remote users to connect to the router using protocols like Telnet or SSH. |
3 | Password | ***** | The password is set to secure access to the router's vty lines. |
Click on save and update once changes have been made.
Instance:
In configuring BGP on a router, the "BGP Instance" section is critical as it defines the unique settings for BGP operations on that particular router.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | AS | Ex: 12 | BGP uses AS numbers to maintain separation between different networks and to prevent routing loops.
This field must not be empty because it is essential for BGP to function correctly. |
2 | Router ID | Ex: 192.168.10.12 | The Router ID is a unique identifier for the BGP instance within an AS. It helps distinguish between multiple routers within the same AS. |
3 | Network Import Check | Enable/Disable | This option enables or disables checking if a route exists in the local routing table before it is advertised to BGP peers. |
4 | Advertise Networks | Ex: 192.168.10.0/24 | This field is used to specify which networks should be advertised to BGP peers. |
5 | Redistribute Options | 1.) None
2.) Kernel Added Routes 3.) Connected Routes 4.) OSPF Routes 5.) NHRP Routes 6.) Static Routes |
None: No routes are redistributed.
Kernel Added Routes: Routes that are added by the kernel are redistributed. Connected Routes: Directly connected routes are redistributed. OSPF Routes: Routes learned through OSPF are redistributed into BGP. NHRP Routes: Routes discovered through NHRP will be advertised to BGP peers. Static Routes: Any static routes defined by an administrator will be advertised to BGP peers. |
6 | Deterministic MED | Enable/Disable | This option, when enabled, ensures that the router uses a deterministic method to select the best path when there are multiple routes with the same AS path length but different MED values. |
Click on save and update once changes have been made.
Peers:
These are other routers with which your router establishes a BGP session to exchange routing information. Peers can be within the same organization or with external networks.
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Ex: Route | This is an identifier that helps you distinguish between different peers or configurations. |
2 | AS | Ex: 12 | BGP uses AS numbers to differentiate between different networks. |
3 | IP Address | Ex: 10.1.1.0 | Specifies the IP address of the BGP peer. |
4 | Update Source | Ex: loopback | Name of the Loopback Interface |
5 | EBGP MultiHop | Ex: 5 | The TTL (Time to Live) value that allows BGP to establish a session with a peer multiple hops away. The value 5 means the BGP peer is up to 5 hops away. |
6 | Password | ***** | Both peers must have the same password configured to establish a secure BGP session. |
7 | Weight | Ex: 100 | A higher weight is preferred, and 100 is a common value for prioritizing routes from this peer. |
8 | Default Originate | Enable/Disable | This setting would be enabled if you want your router to advertise a default route (0.0.0.0/0) to the BGP peer, indicating that your router can be used as a default gateway. |
9 | Next Hop Self | Enable/Disable | This option would be enabled if you want your router to advertise its own IP address as the next hop for routes sent to the BGP peer. |
10 | Inbound Soft Reconfiguration | Enable/Disable | When enabled, this allows for BGP policy changes without resetting the session. |
11 | Hold Time | Ex: 180 (seconds) | The maximum time the router will wait before considering the peer is unreachable. |
12 | Keepalive Time | Ex: 60 (seconds) | It is typically set to one-third of the Hold Time to ensure the peer is still responsive. |
13 | Connect Retry Time | Ex:120 (seconds) | The time the router waits before retrying a connection to the BGP peer if the session fails. |
Peer Groups:
Peer groups allow you to group several peers together and apply the same routing policies to them, simplifying the management of BGP configurations.
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Ex: Route | This is an identifier that helps you distinguish between different peers or configurations. |
2 | AS | Ex: 12 | BGP uses AS numbers to differentiate between different networks. |
3 | Neighbor Address | 192.168.1.2 | This is the IP address of the BGP neighbor (peer) you're establishing a session with. |
4 | Password | **** | Both peers must have the same password configured to establish a secure session. |
5 | Weight | Ex: 100 | A higher weight is preferred. 100 is a common value used to prioritize routes from this peer. |
6 | Inbound Soft Reconfiguration | Enable/Disable | When enabled, this allows for BGP policy changes without resetting the session. |
7 | Hold Time | Ex: 180 (seconds) | The maximum time the router will wait before considering the peer is unreachable. |
8 | Keepalive Time | Ex: 60 (seconds) | It is typically set to one-third of the Hold Time to ensure the peer is still responsive. |
9 | Connect Retry Time | Ex:120 (seconds) | The time the router waits before retrying a connection to the BGP peer if the session fails. |
Click on save and update once changes have been made.
6.3 OSPF
OSPF (Open Shortest Path First) is a link-state protocol, which means it builds a complete map (or topology) of the network and uses that map to calculate the shortest path to each destination.
This section is divided into 5 sub sections,
- Status
- General settings
- Instance
- Network and Area
- Interface
The ‘Status’ section will show the status of the connections made.
General Settings:
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Enable OSPF | Enable/Disable | When you enable OSPF, the router starts participating in OSPF processes, such as exchanging routing information with other OSPF-enabled routers and calculating the shortest path to each network. |
2 | Enable vty | Enable/Disable | vty refers to the Virtual Terminal lines on a router, which allow remote users to connect to the router using protocols like Telnet or SSH. |
3 | Password | ***** | The password is set to secure access to the router's vty lines. |
Click on save and update once changes have been made.
Instance:
This setup enables a well-structured and efficient OSPF deployment, ensuring that the right routes are advertised while keeping the OSPF process streamlined by controlling where OSPF traffic is generated.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Router ID | Ex: 192.168.10.12 | The Router ID identifies the OSPF router uniquely in the network. |
2 | Passive Interfaces | 1.) None
2.) Loopback 3.) Eth 0.5 4.) custom |
None: No interface is set as passive.
loopback: Marks the loopback interface as passive. eth 0.5: Marks the eth0.5 interface as passive. custom: Allows you to specify a custom interface name. Passive interfaces are used when you want to advertise a network in OSPF but do not want to establish OSPF neighbour relationships on that interface, reducing unnecessary OSPF traffic. |
3 | Redistribute Options | 1.) None
2.) Kernel Added Routes 3.) Connected Routes 4.) NHRP Routes 5.) Static Routes 6.) BGP |
None: No routes are redistributed.
Kernel Added Routes: Routes that are added by the kernel are redistributed. Connected Routes: Directly connected routes are redistributed. NHRP Routes: Routes discovered through NHRP will be advertised to BGP peers. Static Routes: Any static routes defined by an administrator will be advertised to BGP peers. BGP: Redistributes routes from Border Gateway Protocol (BGP) into OSPF. |
Click on save and update once changes have been made.
Network and Area:
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Ex: Network | A descriptive name that helps identify the connection |
2 | Network | Ex: 192.168.25.0/24 | This network will be advertised by OSPF to other OSPF routers in the same area. |
3 | Area | Ex: 0.0.0.0 | OSPF areas help segment large networks to reduce routing overhead. Area 0.0.0.0 is the backbone area, and all other areas typically connect through this area. |
Interface:
The interface determines the physical or logical port through which the connection will be routed.
EDIT:
To edit the existing device the user needs to click on the edit option.
Once the changes are done click on the save button to save all the changes.
Click on the deleted button to delete the existing device detail.
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Name | Ex: Route | This name helps distinguish between different connections within the router's configuration. |
2 | Interface | 1.) Loopback
2.) Eth0.5 3.) Custom |
Loopback: Typically used for internal routing within the router, often for the router's own identification (127.0.0.1).
Eth0.5: Refers to a physical or virtual Ethernet interface on the router Custom: Allows you to specify a different or specialized interface, depending on your network setup. |
3 | Priority | Ex: 10, 20 | A lower priority number (e.g., 10) means this route will be preferred over others with a higher number (e.g., 20) when routing decisions are made. |
4 | Cost | Ex: 10 | The cost can be based on bandwidth, where faster links have lower costs.
For example, 10 might be assigned to a high-speed interface, while 100 might be assigned to a slower one. |
5 | Hello Interval | Ex: 10secs | Adjusting the Hello Interval can impact OSPF neighbour formation and stability.
Default is usually 10 seconds for broadcast and point-to-point networks. |
6 | Dead Interval | Ex: 40secs | This interval determines how long OSPF waits before considering a neighbour lost.
Default is usually 40 seconds (four times the Hello Interval). |
7 | Retransmit Interval | Ex: 5secs | It should be set according to the network's performance and reliability. |
8 | Network Type | 1.) Broadcast
2.) Non-broadcast 3.) Point-to-point 4.) Point-to-multipoint |
Broadcast: For Ethernet or other broadcast-capable networks where a DR/BDR is elected.
Non-broadcast: For networks that don't support broadcasting, like Frame Relay, where neighbours must be manually configured. Point-to-point: For direct connections between two routers with no need for a DR/BDR. Point-to-multipoint: For networks with multiple connections that don’t require a DR/BDR. The choice of network type should match the physical and logical topology of the network. |
9 | Authentication | 1.) None
2.) General key 3.) MD5 |
None: No authentication is used.
General key: Uses a simple password (plaintext). MD5: Uses MD5 hash-based authentication, which is more secure. |
Save and update the page once configured.
6.4 Dynamic Routing Custom File Upload
Dynamic Routing Custom File Upload allows you to select and upload a custom configuration file for dynamic routing settings (e.g., OSPF, BGP).
Enable “Upload Custom File”
Upload Custom File:
- Purpose: Finalizes the selection and prepares the file for uploading to the router.
- Expected Action: Click "Upload" after selecting your file.
- Explanation: This action uploads the file to the router, making it available for the router to use or store in its configuration directory.
Once you upload and apply the configuration, the router will update its routing tables or other related settings based on the contents of the custom file.
Use Case:
If you're managing a complex network and need to implement specific dynamic routing protocols or settings not available through the standard router interface, you can upload a custom file with the exact configurations required.
Save and update the page once configured.
6.5 Routing Debug
The "Routing Debug" section provides various utilities and commands to diagnose and monitor routing protocols like BGP (Border Gateway Protocol) and OSPF (Open Shortest Path First).
Specification details are given below:
SN | Field Name | Sample Value | Description |
1 | Show BGP Summary | Command ‘RUN’ | Displays a summary of the BGP sessions, including the status of each BGP neighbour. |
2 | Show BGP Running Config | Command ‘RUN’ | Displays the current running configuration for BGP. |
3 | Show IP BGP | Command ‘RUN’ | Shows the current BGP routing table. |
4 | Refresh BGP Table | Command ‘RUN’ | Refreshes the BGP routing table, which can be useful after making changes to BGP configuration. |
5 | Show BGP Neighbors | Ex: 10.1.1.120 | Displays detailed information about the BGP neighbor with the specified IP address. |
6 | Show Received Routes | Ex: 10.1.1.120 | Shows the routes received from the specified BGP neighbor. |
7 | Run Custom BGP Command | Ex: show ip bgp summary | Allows you to run any custom BGP command to gather specific information. |
8 | Show OSPF Neighbors | router-id | Displays the list of OSPF neighbors and their statuses. |
9 | Show OSPF Route | Command ‘RUN’ | Displays the OSPF routing table, showing routes learned through OSPF. |
10 | Show OSPF Database | Command ‘RUN’ | Shows the OSPF link-state database, which contains all the LSA (Link-State Advertisements) information. |
11 | Show IP Route | Command ‘RUN’ | A list of all routes in the routing table, including destination networks, next hops, and metrics. |
12 | Show IP Rule | Command ‘RUN’ | Shows IP rules that determine routing decisions based on specific criteria. |
13 | Show IP Route Table | Enter a specific command | Displays the content of a specific routing table. |
14 | Show IP Route Get | Ex: 10.1.1.10 (destination IP address) | Information on the route to the destination, including the next hop and outgoing interface. |
15 | Flush IP Routes Cache | Command ‘RUN’ | Clears the IP route cache, forcing the router to rebuild the cache with fresh data. |
16 | Output | Results | The results of the executed commands and utilities are displayed. |
7.Logout
Click on log out option to exit the application.