An up-to-date firewall can help you protect your organization’s network while allowing legitimate business communication to be sent and received. It keeps bad actors out and can be used to keep employees away from insecure or non-work-related sites.
While a firewall provides excellent security and protection, it needs monitoring and management. Monitoring your own firewall is a time-consuming, intensive, and expensive task that requires security expertise and regular upgrades. Many organizations lack the internal expertise, time, and capital to monitor their own firewalls around-the-clock. For these companies, a managed firewall is an affordable, effective solution.
How a Managed Firewall Works
Managed Firewall Service in India
A managed firewall is a service that offers enhanced threat management. Security experts monitor your firewall remotely and can help mitigate any potential threats. To accomplish this, they study your network traffic and learn what normal traffic looks like for your business. When any unusual activity is detected, it can be quickly identified and addressed.
In addition, your provider will perform routine traffic analysis and send regular reports to you so you will have a clear sense of your network traffic patterns and how your managed services team is managing threats to your network.
Expertise Made Affordable by The Economy of Scale
The beauty of IT services like managed firewall is their ability to leverage economies of scale to offer companies the cybersecurity they need, at a price they can afford. In the past, your only option was to create an in-house security solution for your network, which you had to pay for through a capital expenditure.
Here are 3 ways a managed firewall can enhance your company’s operations:
1. Protect against Cyber Crime
Protect against Cyber Crime
Cyber crime is a growing concern for businesses and citizens alike. According to a recent cyber crime report published by research firm Cybersecurity Ventures, cyber attack rates are climbing faster than any other crime and will cost the global economy $6 trillion annually by 2021.
A business that falls prey to a cyber criminal will face serious losses and a tough road ahead. According to a 2017 report published by the Better Business Bureau, half of all businesses would lose their profitability within a month if their critical data was lost.
With a managed firewall, business owners can avoid or mitigate the risk of a cyber attack or breach.
2. Meet compliance requirements
Meet compliance requirements
As the threat level of cyber attacks continues to grow, so does the burden of compliance regulations. Existing regulations such as HIPAA, PCI DSS, and Sarbanes Oxley continue to evolve with ever stricter and more technical compliance requirements. New regulations such as GDPR add to the complexity.
A managed firewall service provider with compliance expertise can ensure your company meets these legal requirements, avoiding the heavy penalties associated with negligence.
3. Ease burden of monitoring
Ease burden of monitoring
The burden of round-the-clock monitoring can be heavy for many SMBs. For example, if you have a small IT department with just one security expert, it’s not possible for your staff to continuously monitor your network.
Most business owners need to stay focused on their core business activities; they don’t have time to become IT security experts. And hiring enough staff for 24/7 monitoring may be too expensive. A managed firewall solution solves both of these problems.
We Can Help
With the support of Managed Edge Security from Firewall Firm, you can shift the burden of network security, compliance, and monitoring to our team of security experts. With Firewall Firm’s Managed Edge Security solution, customers benefit from next-generation firewall services and unified threat mitigation to protect their network, Our experts work diligently to stay on top of emerging threats, current best practices, and compliance requirements.
Our security experts will continuously watch your network for anomalies, strange patterns, or any other indicators of potential threats. We can also take on routine tasks, including security updates and patches, to free your internal resources to help you accomplish more important tasks and projects.
We can provide high levels of security for your network and bill you on a monthly basis, as an OpEx. Through a carefully crafted Service Level Agreement (SLA), we will spell out our responsibilities and what you can expect from us in the event of a cyber attack on your network.
Firewalls can protect your network against unauthorized access and intruders.
As enterprises expand its mission-critical networks with newer applications, many have begun to view network security technologies as the key to prevent intrusion and exposure of critical data. Without protection, companies can experience security breaches resulting in serious damages. The security system that all enterprises should seek to implement in such a situation is a firewall. Firewalls are certainly becoming a critical part of any secure network.
20 TOP MOST PROBLEMS IN FIREWALLS WHICH IMPACT BUSINESS
Failing to save the CONFIGURATION: 90% of the times we don’t save the configuration which gives the problem when we reboot the Firewall or Router.
Configuration done by the Engg is not meeting the company policy
Rules are not used still there in the ACL
Duplicate Rules no documentation of the rules.
Firewall connection exceeds as not taken in account eh VPN or SSL connections while making a DECISIONS or the Firewall is OLD
Memory full issue there is bug in the rules or the configuration making firewall slow or reboots automatically.
Firewall OS is older and new OS is not supported.
Unwanted application are taking lot of bandwidth like video youtube etc. then bring down the productivity of the organisation.
Link problem. The like is not stable and goes down or flaps too much.
NO QOS done for the rules and on the application.
OSPF or BGP not configured properly.
Poor VOIP quality which may be due to link flap or too much bandwidth taken by other applications
Duplexing not done properly.
Passwords are simple or easy to decode authentication is not upto the mark
MS-SQL is open from the outside for the applications via server with just application authentication.
Anti-spoofing not configured on the interfaces
No logging is done for the system changes.
Any TCP or UDP packet can go out.
Proxy services are not stopped
Certification not configured on the firewall to have the ultimate Security.
The Last one is important and no one configures firewall for that (certification)
Every one is thinking that firewall is now matured and nothing is need more.
But after ransomware things have changed.
Affordable Managed Firewall Service with 24×7 Firewall Monitoring
24×7 Firewall Monitoring Services in India
Take advantage of our group of dedicated Firewall professionals to manage, monitor and respond to network attacks.
System Management – Allows you to focus on other tasks.
Proactive Security Monitoring – We watch and respond to Internet attacks so you don’t have to.
Network Monitoring – We monitor the firewall to ensure your network stays connected to the Internet.
Change Management Reporting – You will always know what is going on and what we did to fix it.
Customized to Your Needs – You control the level of service that is right for you.
» Best practice configuration
» Unlimited phone support
» Constant access to Web-based monitoring & reporting
» No charge equipment repair or replacement
» Remote firmware updates
» Quick configuration changes
» Outage notice by e-mail
» After hours emergency response from our certified team
» No contract or extended customer commitment!
» This service is provided on a month-to-month basis.
Managed Firewall Support Services in India
Managed Firewall Support Services in India
Basic Reactive Managed Firewall Support Services
Just $100 Per Month,
Enterprise Proactive Managed Firewall Support Services
Just $600 Per Month,
Managed Firewall Support Services, Firewall Support Service, Firewall support Services Provider in India
Managed Firewall Support Services, Firewall Support Service, Firewall support Services Provider in India
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IT Monteur Provides Load Balancer, Load balancers, Load balancing, Server Load Balancer, Server Load Balancing Solutions, Array Load balancer, F5 Load Balancer, A10 Load Balancer, Load Balancing, Load Balancer, Delhi, New Delhi, Noida, Gurgaon, India
A load balancer is a device that acts as a reverse proxy and distributes network or application traffic across a number of servers. Load balancers are used to increase capacity (concurrent users) and reliability of applications.
In computing, load balancing distributes workloads across multiple computing resources, such as computers, a computer cluster, network links, central processing units or disk drives. Load balancing aims to optimize resource use, maximize throughput, minimize response time, and avoid overload of any single resource.
In computing, load balancing improves the distribution of workloads across multiple computing resources, such as computers, a computer cluster, network links, central processing units, or disk drives. Load balancing aims to optimize resource use, maximize throughput, minimize response time, and avoid overload of any single resource. Using multiple components with load balancing instead of a single component may increase reliability and availability through redundancy. Load balancing usually involves dedicated software or hardware, such as a multilayer switch or a Domain Name System server process.
Load balancing differs from channel bonding in that load balancing divides traffic between network interfaces on a network socket (OSI model layer 4) basis, while channel bonding implies a division of traffic between physical interfaces at a lower level, either per packet (OSI model Layer 3) or on a data link (OSI model Layer 2) basis with a protocol like shortest path bridging.
Internet-based services
One of the most commonly used applications of load balancing is to provide a single Internet service from multiple servers, sometimes known as a server farm. Commonly load-balanced systems include popular web sites, large Internet Relay Chat networks, high-bandwidth File Transfer Protocol sites, Network News Transfer Protocol (NNTP) servers, Domain Name System (DNS) servers, and databases.
Round-robin DNS
An alternate method of load balancing, which does not require a dedicated software or hardware node, is called round robin DNS. In this technique, multiple IP addresses are associated with a single domain name; clients are given IP in round robin fashion. IP is assigned to clients with a short expiration so the client is more likely to use a different IP the next time they access the Internet service being requested.
DNS delegation
Another more effective technique for load-balancing using DNS is to delegate www.example.org as a sub-domain whose zone is served by each of the same servers that are serving the web site. This technique works particularly well where individual servers are spread geographically on the Internet. For example:
one.example.org A 192.0.2.1
two.example.org A 203.0.113.2
www.example.org NS one.example.org
www.example.org NS two.example.org
However, the zone file for www.example.org on each server is different such that each server resolves its own IP Address as the A-record.[2] On server one the zone file for www.example.org reports:
@ in a 192.0.2.1
On server two the same zone file contains:
@ in a 203.0.113.2
This way, when a server is down, its DNS will not respond and the web service does not receive any traffic. If the line to one server is congested, the unreliability of DNS ensures less HTTP traffic reaches that server. Furthermore, the quickest DNS response to the resolver is nearly always the one from the network’s closest server, ensuring geo-sensitive load-balancing[citation needed]. A short TTL on the A-record helps to ensure traffic is quickly diverted when a server goes down. Consideration must be given the possibility that this technique may cause individual clients to switch between individual servers in mid-session.
Client-side random load balancing
Another approach to load balancing is to deliver a list of server IPs to the client, and then to have client randomly select the IP from the list on each connection. This essentially relies on all clients generating similar loads, and the Law of Large Numbers[4] to achieve a reasonably flat load distribution across servers. It has been claimed that client-side random load balancing tends to provide better load distribution than round-robin DNS; this has been attributed to caching issues with round-robin DNS, that in case of large DNS caching servers, tend to skew the distribution for round-robin DNS, while client-side random selection remains unaffected regardless of DNS caching.
With this approach, the method of delivery of list of IPs to the client can vary, and may be implemented as a DNS list (delivered to all the clients without any round-robin), or via hardcoding it to the list. If a “smart client” is used, detecting that randomly selected server is down and connecting randomly again, it also provides fault tolerance.
Server-side load balancers
For Internet services, a server-side load balancer is usually a software program that is listening on the port where external clients connect to access services. The load balancer forwards requests to one of the “backend” servers, which usually replies to the load balancer. This allows the load balancer to reply to the client without the client ever knowing about the internal separation of functions. It also prevents clients from contacting back-end servers directly, which may have security benefits by hiding the structure of the internal network and preventing attacks on the kernel’s network stack or unrelated services running on other ports.
Some load balancers provide a mechanism for doing something special in the event that all backend servers are unavailable. This might include forwarding to a backup load balancer, or displaying a message regarding the outage.
It is also important that the load balancer itself does not become a single point of failure. Usually load balancers are implemented in high-availability pairs which may also replicate session persistence data if required by the specific application.[5]
Scheduling algorithms
Numerous scheduling algorithms, also called load-balancing methods, are used by load balancers to determine which back-end server to send a request to. Simple algorithms include random choice, round robin, or least connections.[6] More sophisticated load balancers may take additional factors into account, such as a server’s reported load, least response times, up/down status (determined by a monitoring poll of some kind), number of active connections, geographic location, capabilities, or how much traffic it has recently been assigned.
Persistence
An important issue when operating a load-balanced service is how to handle information that must be kept across the multiple requests in a user’s session. If this information is stored locally on one backend server, then subsequent requests going to different backend servers would not be able to find it. This might be cached information that can be recomputed, in which case load-balancing a request to a different backend server just introduces a performance issue.[6]
Ideally the cluster of servers behind the load balancer should not be session-aware, so that if a client connects to any backend server at any time the user experience is unaffected. This is usually achieved with a shared database or an in-memory session database, for example Memcached.
One basic solution to the session data issue is to send all requests in a user session consistently to the same backend server. This is known as “persistence” or “stickiness”. A significant downside to this technique is its lack of automatic failover: if a backend server goes down, its per-session information becomes inaccessible, and any sessions depending on it are lost. The same problem is usually relevant to central database servers; even if web servers are “stateless” and not “sticky”, the central database is (see below).
Assignment to a particular server might be based on a username, client IP address, or be random. Because of changes of the client’s perceived address resulting from DHCP, network address translation, and web proxies this method may be unreliable. Random assignments must be remembered by the load balancer, which creates a burden on storage. If the load balancer is replaced or fails, this information may be lost, and assignments may need to be deleted after a timeout period or during periods of high load to avoid exceeding the space available for the assignment table. The random assignment method also requires that clients maintain some state, which can be a problem, for example when a web browser has disabled storage of cookies. Sophisticated load balancers use multiple persistence techniques to avoid some of the shortcomings of any one method.
Another solution is to keep the per-session data in a database. Generally this is bad for performance because it increases the load on the database: the database is best used to store information less transient than per-session data. To prevent a database from becoming a single point of failure, and to improve scalability, the database is often replicated across multiple machines, and load balancing is used to spread the query load across those replicas. Microsoft’s ASP.net State Server technology is an example of a session database. All servers in a web farm store their session data on State Server and any server in the farm can retrieve the data.
In the very common case where the client is a web browser, a simple but efficient approach is to store the per-session data in the browser itself. One way to achieve this is to use a browser cookie, suitably time-stamped and encrypted. Another is URL rewriting. Storing session data on the client is generally the preferred solution: then the load balancer is free to pick any backend server to handle a request. However, this method of state-data handling is poorly suited to some complex business logic scenarios, where session state payload is big and recomputing it with every request on a server is not feasible. URL rewriting has major security issues, because the end-user can easily alter the submitted URL and thus change session streams.
Yet another solution to storing persistent data is to associate a name with each block of data, and use a distributed hash table to pseudo-randomly assign that name to one of the available servers, and then store that block of data in the assigned server.
Load balancer features
Hardware and software load balancers may have a variety of special features. The fundamental feature of a load balancer is to be able to distribute incoming requests over a number of backend servers in the cluster according to a scheduling algorithm. Most of the following features are vendor specific:
Asymmetric load
A ratio can be manually assigned to cause some backend servers to get a greater share of the workload than others. This is sometimes used as a crude way to account for some servers having more capacity than others and may not always work as desired.
Priority activation
When the number of available servers drops below a certain number, or load gets too high, standby servers can be brought online.
TLS Offload and Acceleration
TLS (or its predecessor SSL) acceleration is a technique of offloading cryptographic protocol calculations onto a specialized hardware. Depending on the workload, processing the encryption and authentication requirements of an TLS request can become a major part of the demand on the Web Server’s CPU; as the demand increases, users will see slower response times, as the TLS overhead is distributed among Web servers. To remove this demand on Web servers, a balancer can terminate TLS connections, passing HTTPS requests as HTTP requests to the Web servers. If the balancer itself is not overloaded, this does not noticeably degrade the performance perceived by end users. The downside of this approach is that all of the TLS processing is concentrated on a single device (the balancer) which can become a new bottleneck. Some load balancer appliances include specialized hardware to process TLS. Instead of upgrading the load balancer, which is quite expensive dedicated hardware, it may be cheaper to forgo TLS offload and add a few Web servers. Also, some server vendors such as Oracle/Sun now incorporate cryptographic acceleration hardware into their CPUs such as the T2000. F5 Networks incorporates a dedicated TLS acceleration hardware card in their local traffic manager (LTM) which is used for encrypting and decrypting TLS traffic. One clear benefit to TLS offloading in the balancer is that it enables it to do balancing or content switching based on data in the HTTPS request.
Distributed Denial of Service (DDoS) attack protection
Load balancers can provide features such as SYN cookies and delayed-binding (the back-end servers don’t see the client until it finishes its TCP handshake) to mitigate SYN flood attacks and generally offload work from the servers to a more efficient platform.
HTTP compression
HTTP compression reduces the amount of data to be transferred for HTTP objects by utilising gzip compression available in all modern web browsers. The larger the response and the further away the client is, the more this feature can improve response times. The trade-off is that this feature puts additional CPU demand on the load balancer and could be done by web servers instead.
TCP offload
Different vendors use different terms for this, but the idea is that normally each HTTP request from each client is a different TCP connection. This feature utilises HTTP/1.1 to consolidate multiple HTTP requests from multiple clients into a single TCP socket to the back-end servers.
TCP buffering
The load balancer can buffer responses from the server and spoon-feed the data out to slow clients, allowing the web server to free a thread for other tasks faster than it would if it had to send the entire request to the client directly.
Direct Server Return
An option for asymmetrical load distribution, where request and reply have different network paths.
Health checking
The balancer polls servers for application layer health and removes failed servers from the pool.
HTTP caching
The balancer stores static content so that some requests can be handled without contacting the servers.
Content filtering
Some balancers can arbitrarily modify traffic on the way through.
HTTP security
Some balancers can hide HTTP error pages, remove server identification headers from HTTP responses, and encrypt cookies so that end users cannot manipulate them.
Priority queuing
Also known as rate shaping, the ability to give different priority to different traffic.
Content-aware switching
Most load balancers can send requests to different servers based on the URL being requested, assuming the request is not encrypted (HTTP) or if it is encrypted (via HTTPS) that the HTTPS request is terminated (decrypted) at the load balancer.
Client authentication
Authenticate users against a variety of authentication sources before allowing them access to a website.
Programmatic traffic manipulation
At least one balancer allows the use of a scripting language to allow custom balancing methods, arbitrary traffic manipulations, and more.
Firewall
Firewalls can prevent direct connections to backend servers, for network security reasons.
Intrusion prevention system
Intrusion prevention systems offer application layer security in addition to network/transport layer offered by firewall security.
Use in telecommunications
Load balancing can be useful in applications with redundant communications links. For example, a company may have multiple Internet connections ensuring network access if one of the connections fails. A failover arrangement would mean that one link is designated for normal use, while the second link is used only if the primary link fails.
Using load balancing, both links can be in use all the time. A device or program monitors the availability of all links and selects the path for sending packets. The use of multiple links simultaneously increases the available bandwidth.
Shortest Path Bridging
The IEEE approved the IEEE 802.1aq standard May 2012, also known and documented in most books as Shortest Path Bridging (SPB). SPB allows all links to be active through multiple equal cost paths, provides faster convergence times to reduce down time, and simplifies the use of load balancing in mesh network topologies (partially connected and/or fully connected) by allowing traffic to load share across all paths of a network.[8][9] SPB is designed to virtually eliminate human error during configuration and preserves the plug-and-play nature that established Ethernet as the de facto protocol at Layer 2.
Routing
Many telecommunications companies have multiple routes through their networks or to external networks. They use sophisticated load balancing to shift traffic from one path to another to avoid network congestion on any particular link, and sometimes to minimize the cost of transit across external networks or improve network reliability.
Another way of using load balancing is in network monitoring activities. Load balancers can be used to split huge data flows into several sub-flows and use several network analyzers, each reading a part of the original data. This is very useful for monitoring fast networks like 10GbE or STM64, where complex processing of the data may not be possible at wire speed.
Use in data center networks
Load balancing is widely used in data center networks to distribute traffic across many existing paths between any two servers.[12] It allows more efficient use of network bandwidth and reduces provisioning costs. In general, load balancing in datacenter networks can be classified as either static or dynamic. Static load balancing distributes traffic by computing a hash of the source and destination addresses and port numbers of traffic flows and using it to determine how flows are assigned to one of the existing paths. Dynamic load balancing assigns traffic flows to paths by monitoring bandwidth utilization of different paths. Dynamic assignment can also be proactive or reactive. In the former case, the assignment is fixed once made, while in the latter the network logic keeps monitoring available paths and shifts flows across them as network utilization changes (with arrival of new flows or completion of existing ones). A comprehensive overview of load balancing in datacenter networks has been made available.
Relationship to fail overs
Load balancing is often used to implement failover—the continuation of a service after the failure of one or more of its components. The components are monitored continually (e.g., web servers may be monitored by fetching known pages), and when one becomes non-responsive, the load balancer is informed and no longer sends traffic to it. When a component comes back online, the load balancer begins to route traffic to it again. For this to work, there must be at least one component in excess of the service’s capacity (N+1 redundancy). This can be much less expensive and more flexible than failover approaches where each single live component is paired with a single backup component that takes over in the event of a failure (dual modular redundancy). Some types of RAID systems can also utilize hot spare for a similar effect.
Load balancing refers to spreading a service load among multiple server systems. A hardware load balancer or software-based load balancing tool can ensure maximum service availability by offering network traffic distribution services.
For example, if your business has a primary business domain (e.g., www.yourbusiness.com), you want your site available to your current customers and your potential customers 100 percent of the time. Comparing the top server load balancers (SLBs) and effectively utilizing their load-balancing capabilities will help provide this level of availability.
When technical folks discuss load balancing, they generally mean hardware load balancer devices dedicated to the task of balancing network traffic loads. A hardware load balancer is a server computer with a very specialized operating system tuned to manage network traffic using user-created rules.
From Load Balancers to Application Delivery Controllers
While these hardware load balancer devices have since evolved into what are now called application delivery controllers (ADC), load balancing remains at the heart of an ADC. Enterprises and hosting companies rely on load-balancing and ADC devices to distribute traffic to create highly available services.
In addition to providing simple distributed service to multiple servers, load balancers can help prevent denial-of-service attacks, allow legitimate users uninterrupted access to services, protect against single point of failure outages and prevent traffic bottlenecks to systems.
Today we’ll highlight a handful of the leading hardware load balancers as well as several cloud and software-based load balancer options.
Information Security - InfoSec - Cyber Security - Firewall Providers Company in India
What is Firewall? A Firewall is a network security device that monitors and filters incoming and outgoing network traffic based on an organization's previously established security policies. At its most basic, a firewall is essentially the barrier that sits between a private internal network and the public Internet.
Secure your network at the gateway against threats such as intrusions, Viruses, Spyware, Worms, Trojans, Adware, Keyloggers, Malicious Mobile Code (MMC), and other dangerous applications for total protection in a convenient, affordable subscription-based service. Modern threats like web-based malware attacks, targeted attacks, application-layer attacks, and more have had a significantly negative effect on the threat landscape. In fact, more than 80% of all new malware and intrusion attempts are exploiting weaknesses in applications, as opposed to weaknesses in networking components and services. Stateful firewalls with simple packet filtering capabilities were efficient blocking unwanted applications as most applications met the port-protocol expectations. Administrators could promptly prevent an unsafe application from being accessed by users by blocking the associated ports and protocols.
Firewall Firm is an IT MonteurFirewall Company provides Managed Firewall Support, Firewall providers , Firewall Security Service Provider, Network Security Services, Firewall Solutions India , New Delhi - India's capital territory , Mumbai - Bombay , Kolkata - Calcutta , Chennai - Madras , Bangaluru - Bangalore , Bhubaneswar, Ahmedabad, Hyderabad, Pune, Surat, Jaipur, Firewall Service Providers in India
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