Multi-factor authentication

Multi-factor authentication (MFA) is a method of confirming a user's claimed identity in which a computer user is granted access only after successfully presenting two or more pieces of evidence (or factors) to an authentication mechanism: knowledge (something the user and only the user knows), possession (something the user and only the user has), and inherence (something the user and only the user is).[1][2]

Two-factor authentication (also known as 2FA) is a type (subset) of multi-factor authentication. It is a method of confirming users' claimed identities by using a combination of two different factors: 1) something they know, 2) something they have, or 3) something they are.

A good example of two-factor authentication is the withdrawing of money from an ATM; only the correct combination of a bank card (something that the user possesses) and a PIN (something that the user knows) allows the transaction to be carried out.

Another example of two factor authentication is being frequently used on gmail.com. Every fresh login would ask for the password & a system generated one-time password (OTP) sent on the registered mobile number or email-id.

Two-step verification or two-step authentication is a method of confirming a user's claimed identity by utilizing something they know (password) and a second factor other than something they have or something they are. An example of a second step is the user repeating back something that was sent to them through an out-of-band mechanism. Or the second step might be a six digit number generated by an app that is common to the user and the authentication system. [3]

Authentication factors

The use of multiple authentication factors to prove one's identity is based on the premise that an unauthorized actor is unlikely to be able to supply the factors required for access. If, in an authentication attempt, at least one of the components is missing or supplied incorrectly, the user's identity is not established with sufficient certainty and access to the asset (e.g., a building, or data) being protected by multi-factor authentication then remains blocked. The authentication factors of a multi-factor authentication scheme may include:

  • some physical object in the possession of the user, such as a USB stick with a secret token, a bank card, a key, etc.
  • some secret known to the user, such as a password, PIN, TAN, etc.
  • some physical characteristic of the user (biometrics), such as a fingerprint, eye iris, voice, typing speed, pattern in key press intervals, etc.[4]

Knowledge factors

Knowledge factors are the most commonly used form of authentication. In this form, the user is required to prove knowledge of a secret in order to authenticate.

A password is a secret word or string of characters that is used for user authentication. This is the most commonly used mechanism of authentication. Many multi-factor authentication techniques rely on password as one factor of authentication.[5] Variations include both longer ones formed from multiple words (a passphrase) and the shorter, purely numeric, personal identification number (PIN) commonly used for ATM access. Traditionally, passwords are expected to be memorized.

Many secret questions such as "Where were you born?" are poor examples of a knowledge factor because they may be known to a wide group of people, or be able to be researched.

Possession factors

Possession factors ("something the user and only the user has") have been used for authentication for centuries, in the form of a key to a lock. The basic principle is that the key embodies a secret which is shared between the lock and the key, and the same principle underlies possession factor authentication in computer systems. A security token is an example of a possession factor.

Disconnected tokens

RSA SecurID token, an example of a disconnected token generator.

Disconnected tokens have no connections to the client computer. They typically use a built-in screen to display the generated authentication data, which is manually typed in by the user.[6]

Connected tokens

Connected tokens are devices that are physically connected to the computer to be used. Those devices transmit data automatically.[7] There are a number of different types, including card readers, wireless tags and USB tokens.[7]

Software tokens

A software token (a.k.a. soft token) is a type of two-factor authentication security device that may be used to authorize the use of computer services. Software tokens are stored on a general-purpose electronic device such as a desktop computer, laptop, PDA, or mobile phone and can be duplicated. (Contrast hardware tokens, where the credentials are stored on a dedicated hardware device and therefore cannot be duplicated (absent physical invasion of the device).)

Inherent factors

These are factors associated with the user, and are usually biometric methods, including fingerprint, face, voice, or iris recognition. Behavioral biometrics such as keystroke dynamics can also be used.

Use of mobile phones

Mobile-phone two-step authentication is more secure than single-factor password protection but suffers from some security concerns. Phones can be cloned, apps can run on several phones and cell-phone maintenance personnel can read SMS texts. Not least, cell phones can be compromised in general, meaning the phone is no longer something only the user has.

The major drawback of authentication including something that the user possesses is that the user must carry around the physical token (the USB stick, the bank card, the key or similar), practically at all times. Loss and theft are a risk. Many organizations forbid carrying USB and electronic devices in or out of premises owing to malware and data theft-risks, and most important machines do not have USB ports for the same reason. Physical tokens usually do not scale, typically requiring a new token for each new account and system. Procuring and subsequently replacing tokens of this kind involves costs. In addition, there are inherent conflicts and unavoidable trade-offs between usability and security.[8]

Mobile-phone two-step authentication involving devices such as mobile phones and smartphones was developed to provide an alternative method that would avoid such issues. To authenticate themselves, people can use their personal access-codes to the device (i.e. something that only the individual user knows) plus a one-time-valid, dynamic passcode, typically consisting of 4 to 6 digits. The passcode can be sent to their mobile device by SMS or push notification or can be generated by a one-time-passcode-generator app. In all three cases, the advantage of using a mobile phone is that there is no need for an additional dedicated token, as users tend to carry their mobile devices around at all times.

As of 2018 SMS is the most broadly-adopted multi-factor authentication method for consumer-facing accounts. Notwithstanding the popularity of SMS verification, the United States NIST has condemned it as a form of authentication[9] and security advocates have publicly criticized it.[10]

In 2016 and 2017 respectively, both Google and Apple started offering user two-step authentication with push notification as an alternative method.[11][12]

Security of mobile-delivered security tokens fully depends on the mobile operator's operational security and can be easily breached by wiretapping or SIM cloning by national security agencies.[13]

Advantages

  • No additional tokens are necessary because it uses mobile devices that are (usually) carried all the time.
  • As they are constantly changed, dynamically generated passcodes are safer to use than fixed (static) log-in information.
  • Depending on the solution, passcodes that have been used are automatically replaced in order to ensure that a valid code is always available; acute transmission/reception problems do not therefore prevent logins.

Disadvantages

  • Users must carry a mobile phone, charged, and kept in range of a cellular network, whenever authentication might be necessary. If the phone is unable to display messages, such as if it becomes damaged or shuts down for an update or due to temperature extremes (e.g. winter exposure), access is often impossible without backup plans.
  • Mobile carriers may charge the user for messaging fees.[14]
  • Text messages to mobile phones using SMS are insecure and can be intercepted. Thus third parties can steal and use the token.[15]
  • Text messages may not be delivered instantly, adding additional delays to the authentication process.
  • Account recovery typically bypasses mobile-phone two-factor authentication.[16]
  • Modern smartphones are used both for browsing email and for receiving SMS. Email is usually always logged in. So if the phone is lost or stolen, all accounts for which the email is the key can be hacked as the phone can receive the second factor. So smart phones combine the two factors into one factor.
  • Mobile phones can be stolen, potentially allowing the thief to gain access into the user's accounts.
  • SIM cloning gives hackers access to mobile phone connections. Social-engineering attacks against mobile-operator companies have resulted in the handing over of duplicate SIM cards to criminals.[17]

Advances in mobile two-factor authentication

Advances in research of two-factor authentication for mobile devices consider different methods in which a second factor can be implemented while not posing a hindrance to the user. With the continued use and improvements in the accuracy of mobile hardware such as GPS,[18] microphone,[19] and gyro/acceleromoter,[20] the ability to use them as a second factor of authentication is becoming more trustworthy. For example, by recording the ambient noise of the user's location from a mobile device and comparing it with the recording of the ambient noise from the computer in the same room in which the user is trying to authenticate, one is able to have an effective second factor of authentication.[21] This also reduces the amount of time and effort needed to complete the process.

Legislation and regulation

The Payment Card Industry (PCI) Data Security Standard, requirement 8.3, requires the use of MFA for all remote network access that originates from outside the network to a Card Data Environment (CDE).[22] Beginning with PCI-DSS version 3.2, the use of MFA is required for all administrative access to the CDE, even if the user is within a trusted network.[23]

United States

Details for authentication for Federal Employees and Contractors in the USA are defined with the Homeland Security Presidential Directive 12 (HSPD-12).[24]

Existing authentication methodologies involve the explained three types of basic "factors". Authentication methods that depend on more than one factor are more difficult to compromise than single-factor methods.[25]

IT regulatory standards for access to Federal Government systems require the use of multi-factor authentication to access sensitive IT resources, for example when logging on to network devices to perform administrative tasks[26] and when accessing any computer using a privileged login.[27]

NIST Special Publication 800-63-3 discusses various forms of two-factor authentication and provides guidance on using them in business processes requiring different levels of assurance.[28]

In 2005, the United States' Federal Financial Institutions Examination Council issued guidance for financial institutions recommending financial institutions conduct risk-based assessments, evaluate customer awareness programs, and develop security measures to reliably authenticate customers remotely accessing online financial services, officially recommending the use of authentication methods that depend on more than one factor (specifically, what a user knows, has, and is) to determine the user's identity.[29] In response to the publication, numerous authentication vendors began improperly promoting challenge-questions, secret images, and other knowledge-based methods as "multi-factor" authentication. Due to the resulting confusion and widespread adoption of such methods, on August 15, 2006, the FFIEC published supplemental guidelineswhich states that by definition, a "true" multi-factor authentication system must use distinct instances of the three factors of authentication it had defined, and not just use multiple instances of a single factor.[30]

Security

According to proponents, multi-factor authentication could drastically reduce the incidence of online identity theft and other online fraud, because the victim's password would no longer be enough to give a thief permanent access to their information. However, many multi-factor authentication approaches remain vulnerable to phishing,[31] man-in-the-browser, and man-in-the-middle attacks.[32]

Multi-factor authentication may be ineffective against modern threats, like ATM skimming, phishing, and malware.[33]

In May 2017 O2 Telefónica, a German mobile service provider, confirmed that cybercriminals had exploited SS7 vulnerabilities to bypass SMS based two-step authentication to do unauthorized withdrawals from users bank accounts. The criminals first infected the account holder's computers in an attempt to steal their bank account credentials and phone numbers. Then the attackers purchased access to a fake telecom provider and set-up a redirect for the victim's phone number to a handset controlled by them. Finally the attackers logged into victims' online bank accounts and requested for the money on the accounts to be withdrawn to accounts owned by the criminals. SMS passcodes were routed to phone numbers controlled by the attackers and the criminals transferred the money out.[34]

Implementation considerations

Many multi-factor authentication products require users to deploy client software to make multi-factor authentication systems work. Some vendors have created separate installation packages for network login, Web access credentials and VPN connection credentials. For such products, there may be four or five different software packages to push down to the client PC in order to make use of the token or smart card. This translates to four or five packages on which version control has to be performed, and four or five packages to check for conflicts with business applications. If access can be operated using web pages, it is possible to limit the overheads outlined above to a single application. With other multi-factor authentication solutions, such as "virtual" tokens and some hardware token products, no software must be installed by end users.

There are drawbacks to multi-factor authentication that are keeping many approaches from becoming widespread. Some consumers have difficulty keeping track of a hardware token or USB plug. Many consumers do not have the technical skills needed to install a client-side software certificate by themselves. Generally, multi-factor solutions require additional investment for implementation and costs for maintenance. Most hardware token-based systems are proprietary and some vendors charge an annual fee per user. Deployment of hardware tokens is logistically challenging. Hardware tokens may get damaged or lost and issuance of tokens in large industries such as banking or even within large enterprises needs to be managed. In addition to deployment costs, multi-factor authentication often carries significant additional support costs. A 2008 survey[35] of over 120 U.S. credit unions by the Credit Union Journal reported on the support costs associated with two-factor authentication. In their report, software certificates and software toolbar approaches were reported to have the highest support costs.

Research into deployments of multi-factor authentication schemes[36]has shown that one of the elements that tends to impact the adoption of such systems is the line of business of the organization that deploys the multi-factor authentication system. Examples cited include the U.S. federal government, which employs an elaborate system of physical tokens (which themselves are backed by robust Public Key Infrastructure), as well as private banks, which tend to prefer multi-factor authentication schemes for their customers that involve more accessible, less expensive means of identity verification, such as an app installed onto a customer-owned smartphone. Despite the variations that exist among available systems that organizations may have to choose from, once a multi-factor authentication system is deployed within an organization, it tends to remain in place[36], as users invariably acclimate to the presence and use of the system and embrace it over time as a normalized element of their daily process of interaction with their relevant information system.

Examples

Several popular web services employ multi-factor authentication, usually as an optional feature that is deactivated by default. [37]

See also

References

  1. "Two-factor authentication: What you need to know (FAQ) – CNET". CNET. Retrieved 2015-10-31.
  2. "How to extract data from an iCloud account with two-factor authentication activated". iphonebackupextractor.com. Retrieved 2016-06-08.
  3. "The Difference Between Two-Factor and Two-Step Authentication". lifehacker.com. Retrieved 2018-01-16.
  4. "What is 2FA?". Retrieved 19 February 2015.
  5. "Securenvoy – what is 2 factor authentication?". Retrieved April 3, 2015.
  6. de Borde, Duncan. "Two-factor authentication" (PDF). Archived from the original (PDF) on January 12, 2012.
  7. 1 2 van Tilborg, Henk C.A.; Jajodia, Sushil, eds. (2011). Encyclopedia of Cryptography and Security, Volume 1. Springer Science & Business Media. p. 1305. ISBN 9781441959058.
  8. Anonymous Two-Factor Authentication in Distributed Systems: Certain Goals Are Beyond Attainment (PDF), retrieved 2018-03-23
  9. "NIST is No Longer Recommending Two-Factor Authentication Using SMS". Schneier on Security. August 3, 2016. Retrieved November 30, 2017.
  10. Andy Greenberg (2016-06-26). "So Hey You Should Stop Using Texts For Two-factor Authentication". Wired. Retrieved 2018-05-12.
  11. Tung, Liam. "Google prompt: You can now just tap 'yes' or 'no' on iOS, Android to approve Gmail sign-in". ZD Net. ZD Net. Retrieved 11 September 2017.
  12. Miller, Chance. "Apple prompting iOS 10.3". 9to5 Mac. 9to5 Mac. Retrieved 11 September 2017.
  13. "How Russia Works on Intercepting Messaging Apps – bellingcat". bellingcat. 2016-04-30. Retrieved 2016-04-30.
  14. "Standard Vs. Premium Text Message Charges". Retrieved 2017-07-12.
  15. SSMS – A Secure SMS Messaging Protocol for the M-Payment Systems, Proceedings of the 13th IEEE Symposium on Computers and Communications (ISCC'08), pp. 700–705, July 2008 arXiv:1002.3171
  16. Rosenblatt, Seth; Cipriani, Jason (June 15, 2015). "Two-factor authentication: What you need to know (FAQ)". CNET. Retrieved 2016-03-17.
  17. tweet_btn(), Shaun Nichols in San Francisco 10 Jul 2017 at 23:31. "Two-factor FAIL: Chap gets pwned after 'AT&T falls for hacker tricks'". Retrieved 2017-07-11.
  18. "Location Authentication - Inside GNSS". www.insidegnss.com.
  19. "Continuous voice authentication for a mobile device".
  20. "DARPA presents: Continuous Mobile Authentication - Behaviosec". 22 October 2013.
  21. "Sound-Proof: Usable Two-Factor Authentication Based on Ambient Sound | USENIX". www.usenix.org. Retrieved 2016-02-24.
  22. "Official PCI Security Standards Council Site – Verify PCI Compliance, Download Data Security and Credit Card Security Standards". www.pcisecuritystandards.org. Retrieved 2016-07-25.
  23. "For PCI MFA Is Now Required For Everyone | Centrify Blog". blog.centrify.com. Retrieved 2016-07-25.
  24. US Security Directive as issued on August 12, 2007 and last updated August 19, 2015 Archived September 16, 2012, at the Wayback Machine.
  25. "Frequently Asked Questions on FFIEC Guidance on Authentication in an Internet Banking Environment", August 15, 2006
  26. "SANS Institute, Critical Control 10: Secure Configurations for Network Devices such as Firewalls, Routers, and Switches".
  27. "SANS Institute, Critical Control 12: Controlled Use of Administrative Privileges".
  28. "Digital Identity Guidelines". NIST Special Publication 800-63-3. NIST. June 22, 2017. Retrieved February 2, 2018.
  29. "FFIEC Press Release". 2005-10-12. Retrieved 2011-05-13.
  30. FFIEC (2006-08-15). "Frequently Asked Questions on FFIEC Guidance on Authentication in an Internet Banking Environment" (PDF). Retrieved 2012-01-14.
  31. Brian Krebs (July 10, 2006). "Security Fix – Citibank Phish Spoofs 2-Factor Authentication". Washington Post. Retrieved 20 September 2016.
  32. Bruce Schneier (March 2005). "The Failure of Two-Factor Authentication". Schneier on Security. Retrieved 20 September 2016.
  33. "The Failure of Two-Factor Authentication – Schneier on Security". schneier.com. Retrieved 23 October 2015.
  34. Khandelwal, Swati. "Real-World SS7 Attack — Hackers Are Stealing Money From Bank Accounts". The Hacker News. Retrieved 2017-05-05.
  35. "Study Sheds New Light On Costs, Affects Of Multi-Factor".
  36. 1 2 "Influences on the Adoption of Multifactor Authentication". Libicki, Martin C., Balkovich, Edward, Jackson, Brian A., Rudavsky, Rena, Webb, Katharine Watkins. 2011.
  37. GORDON, WHITSON (3 September 2012). "Two-Factor Authentication: The Big List Of Everywhere You Should Enable It Right Now". LifeHacker. Australia. Retrieved 1 November 2012.

Further reading

  • Brandom, Russell (July 10, 2017). "Two-factor authentication is a mess". The Verge. Retrieved July 10, 2017.
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