Safe, Secure & Reliable Remote Services

Client Trust: "We work hard to earn it."

When it comes to your security, we do not mess around.

All communication between your computer and our secure remote terminal is encrypted using the 256 bit Advanced Encryption Standard. For additional peace of mind you may end your remote session at any time with the click of a button.

In June 2003, the U.S. Government (NSA) announced that AES Encryption was secure enough to protect classified information up to the TOP SECRET level. All our clients receive this same high standard 256-bit encryption because when we assure you that we offer safe, secure and reliable end-to-end remote service, we mean it.

 

State-of-the-Art Security

• End-to-end, 256-bit SSL encryption for compliance with HIPAA, Sarbanes-Oxley and other federal and local legislation

• MD5 Hash for enhanced security and traceability with file transfers

• Hosted at a leading, carrier-grade data center with restricted, secured access, redundant power, dual HVAC, fire detection systems, and 24 x 7 network monitoring

 

JiffyTune HIPAA Considerations

All our services are designed to meet strict security standards, which allows HIPAA regulated entities to meet regulatory guidelines set forth by HIPAA.

In an industry where security is a legal obligation, no one is more trusted than JiffyTune. We are proud to be providing remote support to CPAs, OBGYNs, Dentist offices, Banks, Optometrists, Pediatric care professionals and many others in the industry.

 

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What is Encryption?

For a brief history on encryption please continue reading.

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Encryption is the process of changing data into a form that can be read only by the intended receiver. To decipher the message, the receiver of the encrypted data must have the proper decryption key (password).

In traditional encryption schemes, the sender and the receiver use the same key to encrypt and decrypt data. In this case the key is the password you supply when adding files to your ZIP-file - to unzip the file the same password must be supplied.

Encryption Schemes Used by Jiffytune

AES Encryption

AES stands for Advanced Encryption Standard. AES is a symmetric key encryption technique which will replace the commonly used Data Encryption Standard (DES).

It was the result of a worldwide call for submissions of encryption algorithms issued by the US Government's National Institute of Standards and Technology (NIST) in 1997 and completed in 2000.

The winning algorithm, Rijndael, was developed by two Belgian cryptologists, Vincent Rijmen and Joan Daemen.

AES provides strong encryption and has been selected by NIST as a Federal Information Processing Standard in November 2001 (FIPS-197), and in June 2003 the U.S. Government (NSA) announced that AES is secure enough to protect classified information up to the TOP SECRET level, which is the highest security level and defined as information which would cause "exceptionally grave damage" to national security if disclosed to the public.

The AES algorithm uses one of three cipher key strengths: a 128-, 192-, or 256-bit encryption key (password). Each encryption key size causes the algorithm to behave slightly differently, so the increasing key sizes not only offer a larger number of bits with which you can scramble the data, but also increase the complexity of the cipher algorithm.

We use only the strongest 256-bit encryption when working with out clients.

 

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COMPLETE TECHNICAL OVERVIEW OF OUR SYSTEMS

Trust requires true transparency which is why we are providing this technical overview detailing every aspect of our remote support terminal systems.

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JiffyTune Technology Partners

JiffyTune.com remote services make use of the LogMeIn© RESCUE gateway service. This paper provides an overview of the architecture behind LogMeIn Rescue. Topics discussed include data confidentiality, authentication and authorization, auditing and logging, and hosting highlights.

 

Introduction

Scalability, security, reliability and ease of use. These four characteristics, in no particular order, are what describe a great remote support solution. They, however, do not always go hand-in-hand. It’s easy to find a remote support solution that provides two or maybe three of the above criteria, but a solution that delivers on all four fronts is rare.

LogMeIn, Inc. provides JiffyTune.com with just such a solution with LogMeIn Rescue.

Scalability: Whether you have a single technician or a call center with ten thousand employees, Rescue will get the job done.

Security: Support sessions are protected with end-to-end 256-bit SSL encryption. Support operations must be permitted by the end user before the technician can perform them. Support session logs are stored in a database and can be queried later. Remote control sessions can be recorded to a video file.

Reliability: Rescue is hosted in three carrier-grade datacenters with a fully redundant infrastructure.

Ease of use: Your technicians will be up and running in a matter of hours. Your supported end users will get help with a few clicks. No software has to be installed by either party.

 

Data Confidentiality

Often, “security” is equated to “data confidentiality,” “data confidentiality” is equated to “encryption,” and “encryption” is characterized by the symmetric cipher used and its key length. These misconceptions lead to misnomers such as “256-bit AES secure.” Needless to say, this is misleading.
A secure online system should always meet the following objectives:

• Authentication of the communicating parties
• Negotiation of encryption keys without a man-in-the-middle intercepting them
• Exchange messages confidentially
• Detect if a message has been modified in transit

SSL/TLS, short for Secure Sockets Layer and Transport Layer Security, has been designed to provide support for the above steps. Originally created by Netscape Communications Corporation in the mid-90s, it has since become the de-facto standard for secure communications over the Internet, and has been endorsed by Visa, MasterCard and American Express.

The SSL implementation used by LogMeIn Rescue is OpenSSL (http://www.openssl.org).
LogMeIn always uses the latest available version. At the time of publication, the version employed by Rescue is 0.9.8g.

 

Authentication

In LogMeIn Rescue, the Rescue system is first authenticated to the technician (or rather, the technician’s web browser) with its 2048-bit premium RSA SSL certificate. This ensures that the technician will be entering his username/password into the right website. The technician then logs in to the system with his credentials (more on this in Authentication and Authorization).

The Rescue system is also authenticated to the supported end user. The applet, downloaded and run by the user is signed with LogMeIn’s code signing certificate (based on a 1024-bit RSA key), and this information is typically displayed to the user by their web browser when they are about to run the software.

Administrators can also specify to allow technicians to run an ActiveX applet. This is particularly beneficial in locked-down environments, where unapproved .exe files are nor permitted to be run.

The supported user is not authenticated. It is up to the technician to determine who the user is, either via chat or a telephone conversation. The Rescue system does provide authentication-like mechanisms such as unique PIN codes, but these are used for routing the support session to the correct private or shared queue, and should not be construed as an authentication system.

 

Key Agreement

When a support session starts and a connection is established between the supported user and the technician, their computers must agree on an encryption algorithm and a corresponding key to be used for the duration of the session. The importance of this step is often overlooked, and this is somewhat understandable: it seems like a mundane task that should be simple and straightforward. It is, however, everything but simple: to counter so-called man-in-the-middle attacks (where computer C would position itself between computer A and B and impersonate the other party to both A and B) again, certificates must be employed. Since neither the technician nor the end user have server software and an SSL certificate installed on their computers, they both turn to one of the LogMeIn Rescue servers and perform the initial phase of the key agreement with this computer. Verification of the certificate by both the Technician Console and the end user applet ensures that only a Rescue server can mediate the process.

 

Message Exchange

SSL allows for a wide range of cipher suites to be used and the communicating parties can agree on an encryption scheme they both support. This has two primary purposes: first, the protocol can be extended with new cipher suites without breaking backwards compatibility, and second, newer implementations can drop support for suites that are known to contain cryptographical weaknesses.

Since all three components of the LogMeIn Rescue communications system are under LogMeIn’s control, the cipher suite used by these components is always the same: AES256-SHA in cipher-block chaining mode with RSA key agreement. This means the following:

• The encryption keys are exchanged using RSA private/public key pairs, as described in the previous section
• AES, short for Advanced Encryption Standard, is used as the encryption/decryption algorithm
• The encryption key is 256 bits long
• SHA-1 is used as the basis of message authentication codes (MACs). A MAC is a short piece of information used to authenticate a message. The MAC value protects both a message’s integrity as well as its authenticity, by allowing the communicating parties to detect any changes to the message.
• Cipher-block chaining (CBC) mode ensures that each ciphertext block is dependent on • the plaintext blocks up to that point.

The above ensures that data traveling between the supported end user and the technician are encrypted end-to-end, and only the respective parties have access to the information contained within the message stream.

 

Authentication and Authorization

Authentication and authorization in LogMeIn Rescue serves two distinct purposes. The first one, authentication, ensures that the technician or administrator logging in to the Rescue system is in fact who he claims to be.

Authentication is handled in a very straightforward manner: technicians are assigned login IDs (usually matching their email addresses) and corresponding passwords by their administrators. These credentials are entered into the Login form on the LogMeIn Rescue website at the start of a technician workday.

LogMeIn Rescue also offers significant security benefits with Administrators having a number of options for password policy. These include:

• Requiring a minimum password strength to be implemented. A built-in meter shows Administrators and technicians the strength of the chosen password and helps them to choose a password of the required strength.
• Administrators can enforce a minimum required password strength.
• Forcing technicians to change their Rescue password on the next occasion they log in.
• Specifying a maximum password age

LogMeIn Rescue also allows Administrators to implement a Single Sign-On (SSO) policy. The Security Assertion Markup Language (SAML) is employed and is an XML standard for exchanging authentication and authorization data between security domains, that is, between an identity provider and a service provider. Technicians then have access only to pre-defined applications and a single SSO ID to log in to those applications. At the flick of a switch, a technician’s SSO ID can be disabled.

Authorization, on the other hand, happens very frequently – at least once during every remote support session.

The supported end user, after downloading and running the support applet, will be contacted by a technician. The technician can chat with the end user via the applet, but any further action, such as sending a file or viewing the end user’s desktop, requires express permission from the user.

Administrators can also impose IP address restrictions on their technicians. When selected, the IP addresses available can be restricted to a very narrow list. Technicians assigned to a particular task can then only access Rescue from pre-approved IP addresses for that task.

The administrator of a Technician Group can also disable certain features in the Administration Center. For example, turning off the “Receive Files” checkbox ensures that members of the Technician Group will not be able to receive a file from the end user.

Administrators decide what permissions technicians are granted and, from a security aspect, these are:

• Launch Remote Control	• Reboot
• Launch Desktop Viewing	• Record Sessions
• Send and Receive Files	• Start Private Sessions
• Launch File Manager	• Request Windows Credentials
• Send URL's	• Allow Clipboard Synchronization
• View System Information	• Deploy Scripts

Finally, a “single prompt” can also be implemented. This is intended for lengthy remote support work where the end user might not be present for the entire duration of the session. If this flag is enabled for a Technician Group, then the technicians in that group can request a “global” permission from the end user, and, if granted, will be able to perform actions such as viewing system information or entering a remote control session without being further authorized by the end user.

 

Auditing and Logging

Any remote support solution must place strong emphasis on accountability. LogMeIn Rescue provides two distinct auditing features.

First, the so-called “Chat log” is saved in the Rescue database. The “Chat log” is transmitted to the Rescue servers by the Technician Console in real time, and contains events as well as chat messages that pertain to a particular support session. For example, a log file would display when a remote control session is started or ended, or when a file is sent by the technician to the end user. Accompanying metadata, such as the name and MD5 Hash thumbprint of a transmitted file, is also included in the log when applicable.

The “Chat log” database can be queried from the Administration center. At the time of writing, LogMeIn’s data retention policies stipulate that the contents of the logs will be made available online for two years after the end of a remote support session and archived for two years after that.

To facilitate integration with CRM systems, LogMeIn Rescue can post session details to a URL. Administrators can choose whether to allow chat text to be excluded from these details. Additionally, all records of chat texts between technicians and clients can automatically be omitted from the session details stored at the Rescue Data Center.

Second, LogMeIn Rescue allows the technicians to record the events that transpire during a desktop viewing or remote control session into a video file. This is a very important feature for accountability and liability reasons. The recording files are stored in a directory specified by the technician. In the case of a large support organization, this location should be on a network server. The disk space taken up by these recordings varies widely, and depends entirely on the contents (and compressibility) of the supported end user’s desktop, but based on an analysis of millions of remote control sessions utilizing LogMeIn’s technology, the average disk space requirement for one minute of remote control data is 372 Kbytes.

The recordings are stored direct to AVI or in an intermediate format that can be converted to standard AVI files by the “Rescue AVI Converter” application downloadable from the Support section of the LogMeIn Rescue website.

 

Data Center Architecture

LogMeIn Rescue is hosted in state-of-the-art, secure datacenters that feature:

• Multi-layer security control procedures, biometric entry systems, and 24/7 closed-circuit video and alarm monitoring
• Uninterruptible redundant AC and DC power, onsite backup power generators
• HVAC redundant design with air distribution under raised flooring for maximum temperature control
• Smoke detection system above and below raised floor; double-interlock, pre-action, dry-pipe fire suppression

The LogMeIn Rescue infrastructure itself is highly secure and reliable:

• Redundancy on the server component level: redundant power supplies and fans, RAID-1 mirrored harddisks
• Redundancy on the server level: depending on role, active/passive or active/active  clusters
• Redundancy on the datacenter level: three datacenters (US West Coast, US East Coast and London, UK) with near-instant failover capabilities
• Dual redundant firewalls with only ports 80 and 443 open
• Active/passive database clusters
• Redundant load balancers including SSL
• Load-balanced and redundant web and application server clusters
• Load-balanced and redundant gateway server clusters

 

Conclusion

Choosing a remote support solution is often a decision based on features and pricing. If you are reading this document, then it is likely that LogMeIn Rescue has met your needs in these categories. With the information set forth above, we believe we were able to prove that the architecture behind Rescue provides the right levels of scalability, security, reliability and ease of use.

 

LogMeIn Rescue HIPAA Considerations

Although LogMeIn cannot control the content shared by users during a support session, the LogMeIn Rescue service is designed to meet strict security standards, which allows HIPAA regulated entities to meet regulatory guidelines set forth by HIPAA.

Access Controls

• Define permission-based access on a granular level (such as permitting some technicians with remote view only, but not remote control; or some technicians with no file transfer rights)
• No data from remote PCs are stored on LogMeIn data center servers (only session and chat data are stored). In addition, chat text logs can be removed from session details.
• Permissions can be set so that Technicians do not have file transfer rights, eliminating their ability to take files from remote PCs.
• End user must be present at the remote machine, and permit remote access
• End user maintains control, and can terminate the session at any time
• Permissions can be set so that end user must explicitly allow a technician to use specific functions (remote control, desktop view, file transfer, system information, and reboot & reconnect)
• Access rights are automatically revoked when session is terminated
• Predetermined time of inactivity forces automatic logoff
• Hosted at redundant leading, carrier-grade data centers with restricted, secured access

Audit Controls

• Option for forced session recording, with ability to store audit files on secure network share
• Technician sessions and remote session activity is logged on the host computer to ensure security and maintain quality control (successful logins, unsuccessful logins, remote control started, remote control ended, reboot initiated, logout)
• Person or entity authentication
• The technician’s identity is defined by a unique email address, or via an SSO ID, and the technician must be authenticated
• Excessive number of unsuccessful login attempts (five unsuccessful attempts) will lock the account
• IP address restrictions limit the access technicians have to only those specified.

Transmission Security

• End-to-end 256-bit SSL encryption of all data
• MD5 Hash for enhanced traceability of file transfers

 

An overview of the LogMeIn Rescue Gateway Hand-off process

When the digitally signed Rescue applet is started on a machine:

• It contains a session authentication GUID (Globally Unique Identifier), which has been • embedded in the .exe file as a resource by the site when it was downloaded
• It then downloads a list of available gateways from secure.logmeinrescue.com •
• It picks a gateway from the list and connects to it using SSL; the gateway is authenticated • by the applet using its SSl Certificate
• The gateway authenticates the applet in the database with the GUID and registers that the • user is waiting for a technician

When a session is picked up in the Rescue Technician Console:

• A request is sent to the gateway with the session authentication GUID to relay connections between the Technician Console and the client applet
• The gateway authenticates the connection and starts relaying data at the transport level • (it does not decrypt relayed data)

When a connection relay is started, the parties try to establish a peer-to-peer (P2P) connection:

• The applet starts listening for a TCP connection on a port assigned by Windows •
If the TCP connection cannot be established within a time limit (10 seconds), an attempt is • made to establish a UDP connection with the help of the gateway
• If either a TCP or a UDP connection is established, the parties authenticate the P2P • channel (using the session authentication GUID), and it takes over traffic from the relayed connection
• If a UDP connection has been set up, TCP is emulated on top of the UDP datagrams using • XTCP, an LMI-proprietary protocol based on the BSD TCP stack

Every connection is secured with the SSL protocol (using AES256 encryption with SHA1 MAC).

The Session Authentication GUID is a 128-bit, cryptographically-random integer value.