Patent Description:
Modern warfare and law enforcement are characterized by an increasing need for up-to-date situational awareness. To track down, or to protect against, criminals, paramilitary forces or terrorists, law enforcement personnel and soldiers often have an immediate need for information about what is around the next corner or over the hill.

Hostile forces frequently hide themselves from view or exploit the local terrain to gain tactical advantage or escape from pursuers. In the presence of hostile forces, a simple brick wall, barbed wire fence, a body of water, buildings or even a large open area can be an insurmountable obstacle when time is of the essence and tactical resources are unavailable. An active or undetected threat can make the situation dangerous.

Visible indications, noises or predictable actions can reveal friendly forces and put them at risk. Stealth and surprise, however, are important elements that can give a tactical advantage. An UAV is an aircraft with no pilot on board (Also referred to herein as NUAV, where N is an abbreviation for Nano). UAVs can be remotely controlled (e.g. flown by a pilot/operator at a remote ground control station using a controller) or it can fly autonomously based on preprogrammed flight plans or more complex dynamic automation systems. An UAV may also be referred to as a drone. UAVs equipped with video cameras and positioning devices transmit live pictures and positioning information to the operator of the UAV and allows their operator to perform surveillance tasks and gather information from a safe position without exposing themselves during mission.

Unmanned aerial systems, often referred as drones, are becoming largely popular among general public and businesses. The system includes the actual unmanned aerial system (UAS), the ground control station and the communication link between them. The data transmitted between the ground station and the UAS in both directions, as well as the data stored on the Implementation of an encryption solution for a UAV system has to balance user friendliness against required system security. An important requirement is to allow for encrypted data storage without requiring any password or other specific user actions in order to execute a mission (i.e. time critical actions), but instead require specific actions when reviewing data recorded during the mission.

<CIT> discloses a method including: providing a user's computer with code for providing a unique user name; asking the user for a password; generating an asymmetric key pair having one public key and one private key; encrypting the private key via a hash of the password; generating a file-specific symmetric key specific for the data file; encrypting the data file via the file-specific symmetric key; encrypting the file-specific symmetric key via the public key; where the code is executed by a web browser on the computer; storing the encrypted file-specific symmetric key as a header part of the encrypted data file, and interacting with the file exchange interface of a cloud service which receives the encrypted data file, and storing the encrypted data file and header part.

<CIT> discloses a method for operating a secure device having a plurality of mutually exclusive circuit zones, including a first circuit zone having a first level of security and a second circuit zone having a second level of security less than the first level of security, the method including unpacking a key exchange package including receiving a key exchange package in the second circuit zone, the key exchange package including encrypted key data and processing the encrypted key data using a content key in the first circuit zone to generate decrypted key data and storing the decrypted key data in the first circuit zone without disclosing the decrypted key data into the second circuit zone.

The present application includes a method of combining symmetric and asymmetric cryptography for recording and playing back a video media data stream according to claim <NUM>.

The present application includes the encryption and decryption parts of the method separately, though interacting with each other in a key/key whole manner.

The present application also includes an UAV system, having the above mentioned methods implemented.

The following detailed description of the embodiments herein is accompanied by drawings in order to make it more readily understandable. In the drawings:.

The drawings are not necessarily to scale and the dimensions of certain features may have been exaggerated for the sake of clarity. Symbols, video and pictures will usually be in colour. Emphasis is placed upon illustrating the principle of the embodiments herein.

In the following, the embodiments herein will be discussed and example embodiments described by referring to the accompanying drawings.

The present application relates to encryption of data transmitted between an Unmanned Aerial Vehicle (UAV) and a ground controlling base, and when stored on the ground controlling base.

Symmetric cryptography uses the same cryptographic keys for both encryption and decryption of data. The keys may be identical and often represent a shared secret between two or more parties that can be used to maintain a private information link.

Asymmetrical cryptography, is any cryptographic system that uses pairs of keys: Public keys which may be disseminated widely, and private keys which are known only to the owner. Data is encrypted by the public key, but only the holder of the paired private key can decrypt the data encrypted with the public key.

Because of the computational complexity of asymmetric encryption, it is usually used only for small blocks of data. The symmetric encryption/decryption is based on simpler algorithms and is much faster and less computational demanding.

In a public key encryption system, any person can encrypt data using the public key of the receiver, but such data can be decrypted only with the receiver's private key. For this to work it must be computationally feasible for a user to generate a public and private key-pair to be used for encryption and decryption. The strength of a public key cryptography system relies on the degree of difficulty for a properly generated private key to be determined from its corresponding public key. Security then depends only on keeping the private key private, and the public key may be published without compromising security.

According to embodiments herein, a combination of symmetric and asymmetric cryptography is used to balance user friendliness against required system security.

A public/private key pair is generated when a password is set in the ground control station. The public key may be stored in plaintext and is used as a key encryption key (KEK). Each time a mission is started, a data encryption key is generated (DEK), and the KEK is used to encrypt the DEK. Since the KEK is stored in plaintext, starting a mission will not require user input. The encrypted DEK (E-DEK) is stored together with the encrypted data.

Using the public key as key encryption key, means that the private key may be used as the key decryption key (KDK). The password is put into a password-based key derivation function (KDF) to produce a key for encrypting the KDK. The encrypted KDK may be stored on the ground control station together with the E-DEK and the encrypted data.

To decrypt and view the stored data, the user needs to enter the password. The password is entered into the KDF, thus producing the key that is able to decrypt the KDK. The KDK is then used to decrypt the DEK, which again is used to decrypt the data.

<FIG> illustrate an example embodiment of the present application.

Referring to <FIG>, when setting up a system according to the example embodiment, a public and private key-pair is generated. The public key is stored in plain text in the ground control station, while the private key is encrypted by a password before being stored.

<FIG> illustrates in more details how the private key is encrypted. SCRYPT is used to generate an AES key from the selected password. "Salt" is in this context random data that is used as an additional input to the one-way function that "hashes" the password. SCRYPT is in the illustrated example selected because it is a password-based key derivation function specifically designed to make it costly to perform large-scale custom hardware attacks by requiring large amounts of memory. It is generally designed to be computationally intensive, so that it takes a relatively long time to compute. However, setting up the system is only done occasionally, so the time required will still be negligible.

The AES key generated from the password as illustrated in <FIG> is then further used to perform the actual encryption of the private key (PRIV). This is done by an Advanced Encryption Standard (AES) algorithm in Galois/Counter Mode (AES-GCM). In addition to the private key, an Initialization Vector (IV1) is input to the AES-GCM, generating the ciphertext of PRIV which is stored in the ground control station.

<FIG> illustrates how e.g. video captured by the UAV is encrypted during mission, i.e. in recording mode. First, a data encryption key DEK is generated. DEK is further used as a key to encrypt the video captured by the UAV. DEK itself is encrypted by the public key (PUB) generated in the above described process of setting up the system. Then the ciphertext of the captured video encrypted by DEK and the ciphertext of DEK encrypted by PUB will be stored in the ground control station.

<FIG> illustrates the decryption process when play backing the encrypted video stored on the ground control station. In this process, the password entered at the time when setting up the system is needed. SCRYPT is again used to generate the AES key from the entered password. The AES key is in turn used to decrypt the private key (PRIV) from the ciphertext of PRIV stored on the ground control station also at the time when setting up the system. The decrypted PRIV is further used to decrypt the ciphertext of DEK which was generated by encryption of DEK by PUB at the time the video was recorded. DEK is then used to decrypt the stored ciphertext video which was generated by encryption of the video by DEK at the time the video was recorded. The video is then available for playback on e.g. the ground control station screen.

The different processes in embodiments of the present application can be further summarized in the following general stepwise description:.

It follows from the description of example embodiment of the present application above that the actual encryption and decryption of video is performed by the relatively low computational demanding symmetric cryptography, since the data encryption key DEK is used both for encryption and decryption.

However, a new DEK is generated for, and associated with, each respective video recording, but all DEKs are encrypted and decrypted by the relatively high computational demanding asymmetric cryptography with the same public and private public key pair, which was generated in the setup of the system. The public key is stored in the ground control system as plain text, and the private key is stored as ciphertext, password protected and encrypted in the setup of the system.

Hence, recording of video will require no entry of the password thus making it possible for an instant UAV mission, but the video data will still be dual protected by encryption of both the video data itself and the data encryption key of which it is encrypted. Large amount of data, as video data tends to be, is encrypted and decrypted by symmetric cryptography, while low amount of data, as data encryption and decryption keys tend to be, is encrypted and decrypted by asymmetric cryptography.

The above description discloses different example embodiments for illustrative purposes. A person skilled in the art would realize a variety of different combinations of symbols, symbol designs all being within the scope of the embodiments.

It should be emphasized that the term "comprises/comprising" when used in this specification is taken to specify the presence of stated features, integers, steps or components, but does not preclude the presence or addition of one or more other features, integers, steps, components or groups thereof. It should also be noted that the words "a" or "an" preceding an element do not exclude the presence of a plurality of such elements.

Claim 1:
A method of combining symmetric and asymmetric cryptography for recording and playing back a media data stream, performed by an unmanned aircraft system, UAS, comprising an unmanned aerial vehicle, UAV, and a UAV ground station, the method comprising:
generating, by the UAV ground station, a public key (PUB) and a corresponding private key (PRIV);
password protecting, by the UAV ground station, the private key (PRIV) by means of a password provided to the UAV ground station, wherein the password protecting comprises:
generating an advanced encryption standard encryption standard, AES, key (K) based, at least in part, on the password provided;
encrypting the private key using the AES key and an AES algorithm in Galois/Counter Mode, AES-GCM;
storing the encrypted private key within the UAV ground station; and
erasing the private key from the UAV ground station;
after a first mission is started:
generating, by the UAV, a symmetric data encryption key (DEK),
encrypting, by the UAV, said media data stream by means of the symmetric data encryption key, wherein the media data stream is generated by a media data capturing device of the UAV,
encrypting, by the UAV, the symmetric data encryption key by means of the public key (PUB); and
transmitting the encrypted symmetric data encryption key and the encrypted media data stream to the UAV ground station for storage;
storing, by the UAV ground station, the encrypted symmetric data encryption key and the encrypted media data stream to the UAV ground station from the UAV;
wherein the generating the symmetric data encryption key, the encrypting said media data stream, the encrypting the symmetric data encryption key, and the storing are performed without entry of the password.