The field of the present invention relates generally to cryptographic systems.
Public-key cryptographic systems allow two people to exchange private and authenticated messages without requiring that they first have a secure communication channel for sharing private keys. One of the most widely used public-key cryptosystem is the RSA cryptosystem disclosed in U.S. Pat. No. 4,405,829. The RSA cryptosystem is currently deployed in many commercial systems. It is used by web servers and browsers to secure web traffic, it is used to ensure privacy and authenticity of e-mail, it is used to secure remote login sessions, and it is at the heart of electronic credit-card payment systems. In short, RSA is frequently used in applications where security of digital data is a concern.
According to public-key cryptosystems such as the RSA cryptosystem, each person has a unique pair of keys: a private key that is a secret and a public key that is widely known. This pair of keys has two important properties: (1) the private key cannot be deduced from knowledge of the public key alone, and (2) the two keys are complementary, i.e., a message encrypted with one key of the pair can be decrypted only with the complementary key. In these systems, both the public key and the private key in a pair are generated together as the output of a key generation algorithm that takes as input a random seed. Consequently, in these cryptosystems, people cannot choose a desired public or private key, but must simply use the keys that are generated for them by a key generation algorithm. This has the disadvantage that others cannot encrypt messages to a person until that person generates and publishes a public key. Another problem with this type of cryptosystem is that an impostor can publish a public key and claim that it belongs to someone else. To address this issue, a trusted certificate authority (CA) is used to authenticate individuals and certify to others that the individual's public key is authentic. Unfortunately, this adds complexity to the cryptosystem since a sender must obtain a certificate for every receiver, and must obtain a new certificate every time an existing certificate expires. It also requires receivers to create public keys, publish them, register certificates with the CA, and renew such certificates when they expire.
In 1984 Shamir envisioned a new type of public key encryption scheme (described in A. Shamir, “Identity-based cryptosystems and signature schemes”, in Advances in Cryptology—Crypto '84, Lecture Notes in Computer Science, Vol. 196, Springer-Verlag, pp. 47-53, 1984). According to Shamir's scheme, a person's public key consists of a public identifier, which may be the person's name and network address, or combination of name and e-mail address, social security number, street address, telephone number, or office address. Because the public key is the person's pre-existing public identifier (ID) rather than a key produced from a random seed, this kind of public key cryptosystem is called an identity-based encryption (IBE) scheme. Shamir, however, did not provide a concrete, practical IBE cryptosystem. In fact, Shamir argued that existing cryptosystems (such as RSA) could not be adapted to realize a secure IBE cryptosystem.
In the years since Shamir proposed his IBE scheme there have been several attempts to realize an identity-based cryptosystem. Some proposals require that users not collude. Other proposals require the private key generator (PKG) to spend an impractically long time for each private key generation request. Some proposals require tamper resistant hardware.
In short, there remains a need for improved cryptographic methods and systems.
According to one embodiment of the invention, a method of encrypting a first piece of information to be sent by a sender to a receiver uses an encryption key generated from a second piece of information. A bilinear map and the encryption key are used to encrypt at least a portion of the first piece of information to be sent from the sender to the receiver. The bilinear map may be symmetric or asymmetric. The bilinear map may be based on a Weil pairing or a Tate pairing defined on an algebraic group derived from an elliptic curve. More generally, the bilinear map may be based on a pairing defined on algebraic varieties.
According to one embodiment of the invention, encrypting the portion of the first piece of information can be completed prior to generating a decryption key corresponding to the encryption key.
According to another embodiment of the invention, the second piece of information is known to the receiver prior to the generation of a decryption key corresponding to the encryption key. The second piece of information may comprise a character string such as an e-mail address, name or other identifier associated with the receiver, according to different embodiments of the invention. The second piece of information may also include, according to various embodiments, an attribute associated with the receiver or information corresponding to a time or times, such as a date or series of dates defining one or more time intervals. A decryption key may be provided based on a time that a request for the decryption key is received relative to the information corresponding to a time. According to other embodiments of the invention, the second piece of information may include a message identifier, a credential identifier or a message subject identifier.
According to another embodiment of the invention, a message key is generated from the encryption key using a bilinear map, and a cryptographic hash function is applied to the message key.
According to another embodiment of the invention, encrypting the portion of the first piece of information includes generating a mask from the second piece of information using a bilinear map. The mask is applied to the portion of the second piece of information.
An embodiment of the invention is directed to a method of decrypting ciphertext which has been encrypted by a sender using an identity-based encryption key associated with a receiver. A decryption key derived from the encryption key is obtained. At least a portion of the ciphertext is decrypted using a bilinear map and the decryption key. The bilinear map may be symmetric or asymmetric. The bilinear map may be based on a Weil pairing or a Tate pairing defined on an algebraic group derived from an elliptic curve.
According to another embodiment of the invention, the ciphertext is obtained prior to creating the decryption key. According to another embodiment of the invention, the first piece of information is known to the receiver prior to obtaining the ciphertext and prior to obtaining the decryption key. The decryption key may be obtained by sending a request to a private key generator, including information sent together with the ciphertext.
An embodiment of the invention is directed to a method of generating a decryption key corresponding to an encryption key. An algebraic group, a group action, and a master key are provided. The encryption key is generated based on a first piece of information. The decryption key is generated based on the group action, the master key and the encryption key. According to one embodiment of the invention, the group action is capable of being calculated in polynomial time. According to another aspect of the invention, generation of the decryption key in the absence of the master key would require greater than polynomial time.
Another embodiment of the invention is directed to a method of providing system parameters for a cryptographic system. Algebraic groups 1 and 2 having an order q are provided, together with associated group actions. In addition, a bilinear map is provided that maps pairs of points in 1 to points in 2. In another embodiment, a system parameter representing a member P of G1, and a system parameter representing a member Ppub of G1 are provided, where Ppub is based on the group action of a master key s applied to P. According to other embodiments of the invention, a system parameter representing a set of one or more hash functions H1, H2, H3, or H4 are provided. According to another embodiment of the invention, a system parameter representing a size n of a message space is provided.
According to another embodiment of the invention, the bilinear map may be asymmetric or symmetric. In another embodiment the bilinear map is based on a Weil pairing or a Tate pairing defined on a portion of an elliptic curve.
According to another embodiment of the invention, the algebraic group G1 is defined by an elliptic curve defined over a field of order p and the order q is less than the order p. According to another aspect of the invention, the length of p is at least 1024 bits and the length of q is no greater than 160 bits.
Another embodiment of the invention is directed to a method for managing cryptographic communication including generating shares of a master key. The shares are stored in separate systems. A request from a receiver to obtain a private key is responded to in the separate systems by generating from the respective shares of the master key, corresponding respective shares of the private key. The receiver constructs the private key from the shares of the private key, where the private key corresponds to identifying information of the receiver.
Another embodiment of the invention is directed to a method for communicating between a sender and a receiver. A message to be sent from the sender to the receiver is encrypted, and the message is sent from the sender to the receiver. A request for a decryption key is received from the receiver of the message. After receiving the request for the decryption key, information indicating that the receiver has received the message is generated, and the decryption key is provided to the receiver. According to an embodiment of the invention, a return address of the sender is included in the message, and an acknowledgment that the message has been received is sent to the return address. According to another aspect of the invention, an identification of the message is included in an acknowledgment and the acknowledgment is sent to the sender. According to another aspect of the invention, the encryption key is derived based on a return address of the sender.
Another embodiment of the invention is directed to a method for communicating between a sender and a receiver having a credential. Identifying information of the receiver is obtained. A credential required for the receiver to gain a decryption key is specified, and an encryption key is derived from the identifying information of the receiver and the credential. A message to be sent from the sender to the receiver is encrypted using the encryption key and a bilinear map, and the message is sent from the sender to the receiver. A request for a decryption key is received from the receiver of the message. It is determined whether the receiver has the credential, and if the receiver has the credential, the decryption key is provided to the receiver. The receiver then may use the decryption key and the bilinear map to decrypt the message.
Another embodiment of the invention is directed to a method of communicating between a sender and a receiver involving storing a decryption key on a target system. Sets of decryption keys associated with times messages may be decrypted are derived, and the decryption keys are stored on the target system. An encryption key is derived from a string associated with a time a message is to be decrypted. A message is encrypted using the encryption key. The message is received on the target system, and the message is decrypted using a bilinear map and the corresponding decryption key.
Another embodiment of the invention is directed to a method of communicating between a sender and receiver involving entities having different responsibilities. A set of decryption keys is derived from a master key and a set of strings associated with different responsibilities. The decryption keys are provided to entities having the respective responsibilities. An encryption key is derived from a string associated with one of the different responsibilities. A message to be sent from the sender to the receiver is encrypted using the encryption key and a bilinear map. An entity having a particular responsibility receives the message and decrypts the message using the respective decryption key and the bilinear map. According to one embodiment of the invention, the string corresponding to the particular responsibility comprises a subject line of an e-mail.
The following description provides details of several exemplary embodiments of the cryptographic techniques of the present invention, as well as a technical discussion of the security of the system.
Overview
As is normally the case with modern cryptosystems, the techniques of the present invention are generally implemented on computers connected by a communication medium. Although typically the computers are connected by the Internet or another computer network, any communication medium may be used.
One embodiment of the invention comprises an identity-based encryption system that uses a secret message key derived from identity-based information. The message key may be used by a sender to encrypt a message, and by a receiver to decrypt the message. The secret message key is computed by the sender from an identity-based public key of the receiver. The same message key may be computed by the receiver from the receiver's private key, which is derived from the receiver's identity-based public key. Both sender and receiver compute the same secret key using a bilinear map. For example, in one embodiment, an asymmetric or symmetric bilinear map ê: 0×1→2 is used where 0, 1, 2 are (not necessarily distinct) algebraic groups. In the case where 0 is equal to 1, we say the bilinear map is symmetric and often denote it as ê: 1×1→2. A bilinear map ê that is non-degenerate and efficiently computable will be referred to as an admissible map. It is preferable in some embodiments of the invention that the bilinear map be admissible.
The convention throughout this description will be to denote the group operations of 0 and 1 by addition, and the group operation of 2 by multiplication. For a group of prime order we use * to denote the set *=\{O} where O is the identity element in the group . The set of binary strings of arbitrary length is denoted by {0, 1}*. We use q to denote the group {0, . . . , q−1} under addition modulo q, and we use + to denote the set of positive integers. We note that there is a natural group action of q on given by repeated addition, and we denote the result of the action of an element αεq on an element Pε by aP.
According to another embodiment of the invention, a certain variant (involving the map ê) of the computational Diffie-Hellman problem is hard. In one implementation the map ê is admissible and the orders of 0, 1, 2 have a very large prime factor q. The orders of 0, 1 and 2 may be equal to each other. Without loss of generality, the following description assumes for simplicity that the orders of 0, 1, and 2 are all of prime order q.
In an exemplary embodiment, an admissible map ê: 0×1→2 is used to realize an identity-based cryptosystem, as follows. To encrypt a message, a sender uses a public key QIDε1 associated with a public identifier ID for the intended receiver. To decrypt the encrypted message, the receiver uses a complementary private key dIDε1. The private key is computed from the public key QID, a secret master key sε*q, and a group action of *q on 1. In one embodiment, for example, dID=sQID. Since the secret master key s is known only by a trusted PKG, users normally cannot themselves compute private keys. To obtain a private key, an individual may obtain it from the PKG, preferably after being authenticated. At any time, however, anyone can compute the public key QID associated with any public identifier ID even before the corresponding private key has been determined. For example, in one embodiment the public key QID may be obtained by (1) using a conventional character encoding scheme to map the public identifier ID to a corresponding binary string in {0, 1}*, and (2) using a hash function H1: {0, 1}*→*1 to hash the binary string to the element QID of *1, where the order of QID is q.
In this embodiment, a message intended for a receiver with public identifier ID may be encrypted and decrypted as follows. The admissible map ê may be used by the sender to determine a secret message key. Although the sender and receiver do not share all the same information, using the fact that the map ê is bilinear, they can use different information to compute the same message key. Since each uses information that is private, the message key is a secret.
To illustrate how this approach may be implemented, suppose that the sender has knowledge of elements P and sP in 1. In one embodiment, for example, elements P and Ppub=sP in 1 are published system parameters. Now further suppose the sender privately selects a random rε*q, and uses the receiver's identity-based public key QID to compute gIDr=ê(rQID, sP). The element gIDr is an identity-based secret which the sender may use as a secret message key to perform identity-based encryption of a message to the receiver. The sender may then send an encrypted message together with rP to the receiver. The receiver then receives rP and uses it together with the private key sQID to compute the secret message key gIDr=ê(sQID, rP). This secret message key is equal to the secret message key computed by the sender because of the bilinearity of the ê map. This computed element gIDrε2 is thus an identity-based secret of the sender which the receiver may compute using the element rP and the private key sQID. This secret may be used as a message key for cryptographic communication between the sender and receiver.
Note that the PKG also knows the receiver's private key, so can also compute the secret message key and decrypt the message. The sender, receiver and PKG all have sufficient information to compute the secret message key. No other entity, however, normally has knowledge of the sender's secret r or the receiver's secret sQID. The security of this embodiment is related to the difficulty of computing the secret message key, which is based upon a combination of r, s, and QID using a bilinear map, without knowledge of r or knowledge of sQID.
In one embodiment, the message key gIDr is used to determine a mask which is used to encrypt and decrypt the bits of the message using an XOR operation (denoted by ‘⊕’). Specifically, the ciphertext V of a message M is produced by computing V=M⊕H2(gIDr), where H2: 2→{0, 1}n is a hash function, and n is the bit length of the message. Conversely, the message M is recovered from the ciphertext V by computing M=V⊕H2(gIDr).
In another embodiment, the one-way encryption scheme outlined above is made more secure by converting it into a chosen ciphertext secure system. In one embodiment of the invention, for example, a general technique of Fujisaki-Okamoto is used.
In another embodiment, the master key is broken into components si distributed among several private key generators in a distributed PKG. For a given user with a public key QID based on an identifier ID, each of these private key generators in the distributed PKG computes a private key portion di using Q and its portion si of the master key. These private key portions can be combined by the user and used as a single private key dID to decrypt messages encrypted with QID.
In another embodiment, an ElGamal encryption scheme is provided with built-in key escrow, i.e., where one global escrow key can decrypt ciphertexts encrypted under any public key. In this embodiment, the exemplary system described above is adapted as follows. Suppose that the receiver also has knowledge of elements P and sP. Rather than obtaining a private key from the PKG, the receiver generates a public/private key pair by selecting a random xε*q, computing xP using a group action, and publishing a public key based on the result of the computation. In one embodiment, the public key is xP and the complementary private key is d=x(sP). (Thus, xP plays the role of QID, and d=x(sP)=s(xP) plays the role of dID=sQID.) To encrypt a message to the receiver, the sender as before selects a random r and sends rP to the receiver. Then the receiver knows the pair (rP, x(sP)), where x(sP)=d is a secret, while the sender knows the pair (sP, r(xP)), where r(xP) is a secret. Thus, the sender and receiver both can compute g=e(rP, x(sP))=e(sP, r(xP)), where the second equality follows from the bilinearity of ê. This secret, however, can also be determined from knowledge of the master key s. Using the element rP from the sender, the receiver's public key xP, and the master key s, the message key can be computed by evaluating g=ê(rP, s(xP)). It should be noted that this embodiment makes use of a symmetric bilinear map ê: 1×1→2.
In several embodiments of the invention, 1 is a subgroup of an elliptic curve, and an admissible map ê is constructed from the Weil pairing (or Tate pairing) on the elliptic curve. (Recall that, by definition, a subgroup is not necessarily smaller than the group, i.e., 1 may be the entire elliptic curve). More generally, 1 may be an abelian variety and ê an admissible pairing of its elements. In embodiments using a map ê: 0×1→G2 where 0 and 1 are distinct, 0 also may be a subgroup of an elliptic curve, or more generally, an abelian variety.
In other embodiments, various novel applications of identity-based encryption are provided. New and useful applications of IBE systems are possible by using other types of public identifiers, or enhanced public identifiers. For example, the public identifier ID is not limited to an identifier associated with an individual person, but may be an identifier associated with any type of entity including not just individuals but also organizations, governmental agencies, corporations and the like. It should also be noted that individual identities forming a group may be naturally combined to produce a joint identity for the group with a corresponding group private key. The group's private key need not be issued by a PKG, but is simply the combination of the separate private keys of the entities composing the group. It should be noted that the basic ID specifying the identity of an entity is not limited to the name, e-mail address, address, or social security number of an entity, but could also include other types of information such as domain names, URLs, 9-digit zip codes, tax identification numbers, and so on. In many applications, the public identifier ID will contain some character string known to the public to be uniquely associated with a particular entity or collection of entities. In general, however, the public identifier ID can be any arbitrary character string or other arbitrary information.
Various useful applications of IBE make use of enhanced public identifiers. An enhanced identifier may comprise a type of identifier that contains information not necessarily limited to information specifying the identity of a particular entity. For example, an ID can contain a credential descriptor such as a license number, official title, or security clearance associated with an entity. An agency can then manage the credentials by providing private keys only to entities it certifies. In one exemplary embodiment, an ID can contain a property descriptor such as a serial number, vehicle identification number, patent number, or the like. An agency responsible for registering property owners and authenticating owners can manage property registration by providing private keys only to entities that it registers as true owners. More generally, an association between two or more things can be managed by including identifiers for them in an ID. The PKG then acts as the management authority for the associations between things.
Another type of enhanced ID is an identifier that includes a time, a time interval, or a set of time intervals. A private key for such an identifier can then be constructed to automatically expire at a certain time, to automatically activate only after a certain time, or to be valid only for one or more specified time intervals. This technique can be combined with the credential and ownership management to control the time of activation and/or expiration.
From the above examples, it is evident that an identity-based encryption systems according to the present invention are not limited to any particular type of identifier. Thus, the term ‘identity-based’ should be understood in general terms as indicating that any arbitrary character string or other arbitrary information may be used as a basis.
According to another embodiment, an IBE system allows the delegation of decryption capabilities. An entity can set up its own IBE system with its own secret master key, and assume the role of PKG for this IBE system. Because the entity has the master key, it can issue keys to delegate decryption capabilities to others. For example, if the entity is a corporation, the employees can obtain private keys from the corporate PKG. Individuals can be issued private keys matching their names, titles, duties, projects, cases, or any other task-related identifier. In another example, an individual can issue to a laptop private keys that are valid only for the duration of a business trip. If the laptop is lost or stolen, only the keys for that time period are compromised. The master key, which remained at home, is uncompromised.
It should also be pointed out that the medium of communication need not be limited to e-mail or the Internet, but could include any communication medium such as printed publications, digital storage media, radio broadcasting, wireless communications, and so on.
Definitions
Identity-Based Encryption. An exemplary embodiment of an identity-based encryption system and method E uses four randomized algorithms: Setup, Extract, Encrypt, Decrypt:
In an identity-based cryptosystem according to an embodiment of the invention, the above algorithms are used together as illustrated in
Chosen ciphertext security. Chosen ciphertext security (IND-CCA) is the standard acceptable notion of security for a public key encryption scheme. An embodiment of an identity-based encryption system and method may be implemented to satisfy this strong notion of security. Additionally, the selected level of chosen ciphertext security may be strengthened a bit. The reason is that when an adversary attacks a public key ID in an identity-based system, the adversary might already possess the private keys of users ID1, . . . , IDn of her choice. In an embodiment of the invention, the system remains secure under such an attack. That is, the system remains secure even when the adversary can obtain the private key associated with any identity IDi of her choice (other than the public key ID being attacked). We refer to such queries as private key extraction queries. The system of this embodiment also remains secure even though the adversary is challenged on a public key ID of her choice (as opposed to a random public key).
We say that an embodiment of an identity-based encryption system or method is semantically secure against an adaptive chosen ciphertext attack (IND-ID-CCA) if no polynomially bounded adversary A has a non-negligible advantage against the Challenger in the following IND-ID-CCA game:
Note that the standard definition of chosen ciphertext security (IND-CCA) is the same as above except that there are no private key extraction queries and the adversary is challenged on a random public key (rather than a public key of her choice). Private key extraction queries are related to the definition of chosen ciphertext security in the multiuser settings. After all, our definition involves multiple public keys belonging to multiple users. A multiuser IND-CCA may be reducible to single user IND-CCA using a standard hybrid argument. This does not hold in the identity-based settings, IND-ID-CCA, since the adversary gets to choose which public keys to corrupt during the attack. To emphasize the importance of private key extraction queries we note that one implementation of the disclosed IBE system can be modified (by removing one of the hash functions) into a system which has chosen ciphertext security when private extraction queries are disallowed. However, the implementation is insecure when extraction queries are allowed.
Semantically secure identity based encryption. The proof of security for an implementation of our IBE system makes use of a weaker notion of security known as semantic security (also known as semantic security against a chosen plain-text attack). Semantic security is similar to chosen ciphertext security (IND-ID-CCA) except that the adversary is more limited; it cannot issue decryption queries while attacking the challenge public key. For a standard public key system (not an identity based system) semantic security is defined using the following game: (1) the adversary is given a random public key generated by the challenger, (2) the adversary outputs two equal length messages M0 and M1 and receives the encryption of Mb from the challenger where b is chosen at random in {0, 1}, (3) the adversary outputs b′ and wins the game if b=b′. The public key system is said to be semantically secure if no polynomial time adversary can win the game with a non-negligible advantage. As shorthand we say that a semantically secure public key system is IND-CPA secure. Semantic security captures our intuition that given a ciphertext the adversary learns nothing about the corresponding plain-text.
To define semantic security for identity based systems (denoted IND-ID-CPA) we strengthen the standard definition by allowing the adversary to issue chosen private key extraction queries. Similarly, the adversary is challenged on a public key ID of her choice. We define semantic security for identity based encryption schemes using an IND-ID-CPA game. The game is identical to the IND-ID-CCA game defined above except that the adversary cannot make any decryption queries. The adversary can only make private key extraction queries. We say that an identity-based encryption scheme is semantically secure (IND-ID-CPA) if no polynomially bounded adversary has a non-negligible advantage against the Challenger in the following IND-ID-CPA game:
One embodiment of the invention is directed to an IBE system that makes use of a map ê: 1×1→2 between groups 1 and 2 of order q for some large prime q. A map ê may be called an admissible map if it satisfies the following properties:
The existence of the admissible map ê: 1×1→2 as above has two direct implications to these groups.
Since the Decision Diffie-Hellman problem (DDH) in 1 is easy, embodiments of the invention do not use DDH to build cryptosystems in the group 1. Instead, the security in embodiments of our IBE system is based on a novel variant of the Computational Diffie-Hellman assumption called the Bilinear Diffie-Hellman Assumption (BDH).
Bilinear Diffie-Hellman Problem. Let 1, 2 be two groups of prime order q. Let ê: 1×1→2 be an admissible map and let P be a generator of 1. The BDH problem in (1, 2, ê> is as follows: Given <P, aP, bP, cP> for some a, b, cε*q compute W=ê(P, p)abcε2. An algorithm A has advantage ε in solving BDH in <1, 2, ê if
Pr[(P,aP,bP,cP)=ê(P,P)abc]≧ε
where the probability is over the random choice of a, b, c in *q, the random choice of Pε*1, and the random bits of .
BDH Parameter Generator. We say that a randomized algorithm is a BDH parameter generator if (1) takes a security parameter kε+, (2) runs in polynomial time in k, and (3) outputs a prime number q, the description of two groups 1, 2 of order q, and the description of an admissible map ê: 1×1→2. We denote the output of G by (1k)=<q, 1, 2, ê>. The security parameter k is used to determine the size of q; for example, one could take q to be a random k-bit prime. For i=1, 2 we assume that the description of the group i contains polynomial time (in k) algorithms for computing the group action in i and contains a generator of i. The generator of i enables us to generate uniformly random elements in i. Similarly, we assume that the description of ê contains a polynomial time algorithm for computing ê. We give an example of a BDH parameter generator below in the detailed example of an IBE system using the Weil pairing.
Bilinear Diffie-Hellman Assumption. Let be a BDH parameter generator. We say that an algorithm has advantage ε(k) in solving the BDH problem for if for sufficiently large k:
We say that satisfies the BDH assumption if for any randomized polynomial time (in k) algorithm and for any polynomial fε[x] algorithm solves the BDH problem with advantage at most 1/ƒ(k). When satisfies the BDH assumption we say that BDH is hard in groups generated by .
In the description below of a detailed example of an IBE system we give some examples of BDH parameter generators that are believed to satisfy the BDH assumption.
Hardness of BDH. It is interesting to study the relationship of the BDH problem to other hard problems used in cryptography. Currently, all we can say is that the BDH problem in <1, 2, ê> is no harder than the CDH problem in 1 or 2. In other words, an algorithm for CDH in 1 or 2 is sufficient for solving BDH in (1, 2, ê). The converse is currently an open problem: is an algorithm for BDH sufficient for solving CDH in 1 or in 2?
We note that in a detailed example of an IBE system below, the isomorphisms from 1 to 2 induced by the admissible map are believed to be one-way functions. More specifically, for a point Qε*1 define the isomorphism ƒQ: 1→2 by ƒQ(P)=ê(P, Q). If any one of these isomorphisms turns out to be invertible, then BDH is easy in (1, 2, ê>. Fortunately, an efficient algorithm for inverting ƒQ would imply an efficient algorithm for deciding DDH in the group 2. In the exemplary embodiments DDH is believed to be hard in the group 2. Hence, the isomorphisms ƒQ: 1 →2 induced by the admissible map are believed to be one-way functions.
Exemplary Identity-Based Encryption Scheme
We describe the following exemplary embodiments in stages. First we describe a basic identity-based encryption system and method which is not secure against an adaptive chosen ciphertext attack. Another embodiment described below extends the basic scheme to get security against an adaptive chosen ciphertext attack (IND-ID-CCA) in the random oracle model. We later relax some of the requirements on the hash functions to provide alternative embodiments. These embodiments are described with reference to a generic BDH parameter generator satisfying the BDH assumption. Later we describe a detailed example of an IBE system using the Weil pairing.
BasicIdent
The following describes a basic embodiment, called BasicIdent. We present the embodiment by describing the four algorithms: Setup, Extract, Encrypt, Decrypt. We let k be the security parameter given to the setup algorithm. We let be some BDH parameter generator.
The security of the exemplary system is based on the assumption that a variant of the Computational Diffie-Hellman problem in 1 is hard. The technical security details of the encryption scheme are discussed by the inventors in D. Boneh, M. Franklin, “Identity based encryption from the Weil pairing”, extended abstract in Advances in Cryptology—Crypto 2001, Lecture Notes in Computer Science, Vol. 2139, Springer-Verlag, pp. 231-229, 2001, which is incorporated herein by reference.
In an exemplary embodiment, the performance of the system is comparable to the performance of ElGamal encryption in *p. The security of the exemplary system is based on a variant of the computational Diffie-Hellman assumption. Based on this assumption we show that the exemplary system has chosen ciphertext security in the random oracle model. In accordance with a distributed PKG embodiment, threshold cryptography techniques allow the PKG to be distributed so that the master-key is never available in a single location. Unlike common threshold systems, we show that robustness for the distributed PKG embodiment is free.
To argue about the security of the exemplary system, we define chosen ciphertext security for identity-based encryption. Our model gives the adversary more power than the standard model for chosen ciphertext security. First, we allow the attacker to attack an arbitrary public key ID of her choice. Second, while mounting a chosen ciphertext attack on ID we allow the attacker to obtain from the PKG the private key for any public key of her choice, other than the private key for ID. This models an attacker who obtains a number of private keys corresponding to some identities of her choice and then tries to attack some other public key ID of her choice. Even with the help of such queries, it is desirable that the attacker still have negligible advantage in defeating the semantic security of the system.
The following theorem shows that BasicIdent is a semantically secure identity based encryption scheme (IND-ID-CPA) assuming BDH is hard in groups generated by .
Theorem 1 Suppose the hash functions H1, H2 are random oracles. Then BasicIdent is a semantically secure identity based encryption scheme (IND-ID-CPA) assuming BDH is hard in groups generated by . Concretely, suppose there is an IND-ID-CPA adversary that has advantage ε(k) against the scheme BasicIdent. Suppose makes at most qE>0 private key extraction queries and qH
Here e≈2.71 is the base of the natural logarithm. The running time of is O(time()).
To prove the theorem we first define a related Public Key Encryption scheme (not an identity based scheme), called BasicPub. BasicPub is described by three algorithms: keygen, encrypt, decrypt.
According to one embodiment of the invention, a technique of Fujisaki and Okamoto (described in E. Fujisaki and T. Okamoto, “Secure integration of asymmetric and symmetric encryption schemes”, in Advances in Cryptology—Crypto '99, Lecture Notes in Computer Science, Vol. 1666, Springer-Verlag, pp. 537-554, 1999, which is incorporated herein by reference) may be appropriately adapted to convert the BasicIdent embodiment of the previous section into a chosen ciphertext secure embodiment of an IBE system (in the sense defined earlier) in the random oracle model. Let be a probabilistic public key encryption scheme. We denote by pk(M; r) the encryption of M using the random bits r under the public key pk. Fujisaki-Okamoto define the hybrid scheme hy as:
pkhy(M)=<pk(σ;H3(σ,M)),H4(σ)⊕M>
Here σ is generated at random and H3, H4 are cryptographic hash functions. Fujisaki-Okamoto show that if is a one-way encryption scheme then hy is a chosen ciphertext secure system (IND-CCA) in the random oracle model (assuming pk satisfies some natural constraints). We note that semantic security implies one-way encryption and hence the Fujisaki-Okamoto result also applies if is semantically secure (IND-CPA).
We apply the Fujisaki-Okamoto transformation to BasicIdent and show that the resulting embodiment of an IBE system is IND-ID-CCA secure. We obtain the following IBE embodiment which we call FullIdent. Recall that n is the length of the message to be encrypted.
The proof of Theorem 4 is based on the following result of Fujisaki and Okamoto. Let BasicPubhy be the result of applying the Fujisaki-Okamoto transformation to BasicPub.
Theorem 5 (Fujisaki-Okamoto) Suppose is an IND-CCA adversary that achieves advantage ε(k) when attacking BasicPubhy. Suppose has running time t(k), makes at most qD decryption queries, and makes at most qH
Here q is the size of the groups 1, 2 and n is the length of σ.
In fact, Fujisaki-Okamoto prove a stronger result: Under the hypothesis of Theorem 5, BasicPubhy would not even be a one-way encryption scheme. For our purposes the result in Theorem 5 is sufficient. To prove Theorem 4 we also need the following lemma to translate between an IND-ID-CCA chosen ciphertext attack on FullIdent and an IND-CCA chosen ciphertext attack on BasicPubhy.
Lemma 6 Let A be an IND-ID-CCA adversary that has advantage ε(k) against FullIdent. Suppose makes at most qE>0 private key extraction queries and at most qD decryption queries. Then there is an IND-CCA adversary that has advantage at least
against BasicPubhy. Its running time is O(time()).
Proof of Theorem 4. By Lemma 6 an IND-ID-CCA adversary on FullIdent implies an IND-CCA adversary on BasicPubhy. By Theorem 5 an IND-CCA adversary on BasicPubhy implies an IND-CPA adversary on BasicPub. By Lemma 3 an IND-CPA adversary on BasicPub implies an algorithm for BDH. Composing all these reductions gives the required bounds. □
Relaxing the Hashing Requirements
Recall that an IBE system of Section uses a hash function H1: {0, 1}*→*1. The detailed example of an IBE system presented in the next section uses 1 as a subgroup of the group of points on an elliptic curve. In practice, it sometimes can be difficult to build hash functions that hash directly onto such groups. In an exemplary embodiment, we therefore show how to relax the requirement of hashing directly onto *1. Rather than hash onto *1 we hash onto some set A⊂{0, 1}* and then use a deterministic encoding function to map A onto *1.
Admissible encodings: Let 1 be a group and let Aε{0, 1}* be a finite set. We say that an encoding function L: A→*1 is admissible if it satisfies the following properties:
In this section we use FullIdent′ to describe a detailed example of an embodiment of an IBE system. This embodiment is based on the Weil pairing. Although in practice the Tate pairing has computational advantages and may be used instead of the Weil pairing in various embodiments, the implementation using the Weil pairing will be described first because it is simpler. Later, the Tate pairing will be discussed.
Properties of the Weil Pairing
Let p>3 be a prime satisfying p=2 mod 3 and let q be some prime factor of p+1. Let E be the elliptic curve defined by the equation y2=x3+1 over p. We state a few elementary facts about this curve E. From here on we let E(p
The BDH parameter generator 1 is believed to satisfy the BDH assumption asymptotically. However, there is still the question of what values of p and q can be used in practice to make the BDH problem sufficiently hard. It is desirable that we can ensure, at the very least, that the discrete log problem in 1 is sufficiently hard. As pointed out earlier, the discrete log problem in 1 is efficiently reducible to discrete log in 2. Hence, computing discrete log in *p
An Admissible Encoding Function: MapToPoint
Let 1, 2 be two groups generated by 1 as defined above. Recall that an IBE system discussed earlier uses a hash function H1: {0, 1}*→*1. It suffices to have a hash function H1: {0, 1}*→A for some set A, and an admissible encoding function L: A→*1. In what follows the set A will be p, and the admissible encoding function L will be called MapToPoint, which may be used in various embodiments of the present invention.
In this example, let p be a prime satisfying p=2 mod 3 and p=lq−1 for some prime q>3. In this exemplary embodiment, q does not divide l (i.e. q2 does not divide p+1). Let E be the elliptic curve y2=x3+1 over p. Let 1 be the subgroup of points on E of order q. In addition, a hash function H1: {0, 1}*→p is provided.
In this exemplary embodiment, algorithm MapToPoint works as follows on input y0εp:
1. Compute x0=(y02−1)1/3=(y02−1)(2p−1)/3εp.
2. Let Q=(x0, y0)εE(p) and set QID=lQε1.
3. Output MapToPoint (y0)=QID.
This completes the description of MapToPoint.
We note that there are l−1 values of y0εp for which lQ=l(x0, y0)=O (these are the non-O points of order dividing l). Let B⊂p be the set of these y0. When H1(ID) is one of these l−1 values QID is the identity element of 1. It is extremely unlikely for H1(ID) to hit one of these points—the probability is 1/{dot over (q)}<½k. Hence, for simplicity we say that H1(ID) only outputs elements in p\B, i.e. H1: {0, 1}*→p\B. In other embodiments, algorithm MapToPoint can be easily extended to handle the values y0εB by hashing ID multiple times using different hash functions.
Proposition 8 MapToPoint: p\B→*1 is an admissible encoding function.
Proof The map is clearly computable and is a l-to-1 mapping. It remains to show that L is samplable. Let P be a generator of E(p). Given a Qε*1 the sampling algorithm s does the following: (1) pick a random bε{0, . . . , l−1}, (2) compute Q′=l−1·Q+bqP=(x, y), and (3) output s(Q)=yεp. Here l−1 is the inverse of l in *q. This algorithm outputs a random element from the l elements in MapToPoint−1(Q) as required. □
A Detailed Example of an IBE System
Using the BDH parameter generator 1 and the admissible encoding function MapToPoint we obtain the following detailed example of an embodiment of an IBE system.
Embodiments of our IBE system work with efficiently computable bilinear maps ê: 1×1→2 between two groups 1, 2 where the BDH assumption holds. Many different elliptic curves may give rise to such maps. For example, one could use the curve y2=x3+x over p with p=3 mod 4 and its endomorphism φ: (x, y)→(−x, iy) where i2=−1.
In an alternative embodiment, one may use a family of nonsupersingular elliptic curves over p discussed by Miyaji et al. (A. Miyaji, M. Nakabayashi, S. Takano, “New explicit condition of elliptic curve trace for FR-reduction”, IEICE Trans. Fundamentals, Vol. E84 A, No. 5, May 2001). For example, to use a curve E/p in this family one can take 1 to be a cyclic subgroup of E(p
Asymmetric Pairings
As mentioned earlier, embodiments of our IBE system are not limited to symmetric maps, but may include asymmetric maps as well. In other words, embodiments generally may use maps of the form ê: 0×1→2 where 0, 1 are groups of prime order q. When 0 and are equal we say the map is symmetric. When 0 and 1 are not equal we say the map is asymmetric.
The elements QID and P in the asymmetric case are members of 0 and 1, respectively (or vice versa), and the target group of the hash function H1 is selected accordingly. However, to make the proof of security go through (Lemma 2 in particular) we use a slightly strange looking complexity assumption which we call the co-BDH assumption: given random P, aP, bPε1 and Q, aQ, cQε0 no polynomial time algorithm can compute ê(P, Q)abc with non-negligible probability. If one is uses this assumption then for embodiments using a curve E/p from Miyaji et al. (as just described above) one can take 1 to be a cyclic subgroup of E(p) of order q and 0 to be a different cyclic subgroup of E(p
Distributed PKG
In exemplary embodiments of an IBE system it is desirable that the master-key stored at the PKG be protected. One way of protecting this key is by distributing it among different sites using techniques of threshold cryptography. Embodiments of our IBE system support this in a very efficient and robust way. Recall that in some embodiments discussed above, the master-key may be some sε*q and the PKG uses the group action to compute a private key from s and QID, where QID is derived from the user's public key ID. For example, dID=sQID. A distributed PKG embodiment can be implemented in a t-out-of-n fashion by giving each of the n PKGs one share si of a Shamir secret sharing of s mod q. Each of the n PKGs can use its share si of the master key to generate a corresponding share di of a private key dID by calculating di=siQID. The user can then construct the entire private key dID by requesting from t of the n PKGs its share di of the private key, then combining the shares by calculating
where the λi's are the appropriate Lagrange interpolation coefficients.
Furthermore, it is easy to make this embodiment robust against dishonest PKGs using the fact that DDH is easy in 1. During setup each of the n PKGs publishes Pi=siP. During a key generation request the user can verify that the response from the i'th PKG is valid by testing that:
ê(di,P)=ê(QID,Pi)
Thus, a misbehaving PKG will be immediately caught. There is no need for zero-knowledge proofs as in regular robust threshold schemes. The PKG's master-key can be generated in a distributed fashion using the techniques of R. Gennaro et al. (R. Gennaro, S. Jarecki, H. Krawczyk, T. Rabin, “Secure Distributed Key Generation for Discrete-Log Based Cryptosystems”, Advances in Cryptology—Eurocrypt '99, Lecture Notes in Computer Science, Vol. 1592, Springer-Verlag, pp. 295-310, 1999). Using this technique, the PKGs can execute a cooperative protocol that allows them to jointly generate their respective shares of the master key without the master key ever existing in any one place.
Note that a distributed master-key embodiment also enables threshold decryption on a per-message basis, without any need to derive the corresponding decryption key. For example, threshold decryption of BasicIdent ciphertext (U, V) is straightforward if each PKG responds with ê(siQID, U).
Sender system 501 sends a message to receiver 502. The message 514 may be encrypted using a public key based on an identifier ID of the receiver. In order to obtain the corresponding private key, the receiver system queries two of the three PKGs using, for example, the receiver's identity or public key. As shown in the figure, receiver system 502 makes queries 506 and 507 to PKG A 503 and PKG B 504, respectively, in order to obtain two shares of the private key. In response to the queries, PKG A 503 and PKG B 504 return, respectively, share d1, 508, and share d2, 509, of private key d, 510. Receiver system 502 is then able to assemble the corresponding private key dID, which corresponds to the public key with which the message 514 was encrypted. More generally, the receiver could have selected to query any two of the three PKGs. For example, receiver system 502 alternatively could have queried PKGs B and C and combined private key shares d2 and d3 to produce the private key 510. These techniques easily generalize to provide similar embodiments using t-out-of n sharing.
Sender system 501, receiver system 502 as well as PKGs 503, 504 and 505 may be each implemented as computer systems which include elements such as processors and computer-readable media such as memory and other storage devices. Communication between the respective elements may take place using data packets sent over data networks, or any of various other forms of electronic and data transmission and communication. The communication may transpire over various architectures of communication, such as a computer network, such as the Internet, with various wired, wireless and other communications media.
Working in Subgroups
In an alternative embodiment of the detailed IBE system described above, performance may be improved by working in a comparatively small subgroup of the curve. For example, choose a 1024-bit prime p=2 mod 3 with p=aq−1 for some 160-bit prime q. The point P is then chosen to be a point of order q. Each public key ID is converted to a group point by hashing ID to a point Q on the curve and then multiplying the point by a. The system is secure if the BDH assumption holds in the group generated by P. The advantage of this embodiment is that the Weil computation is done on points of small order, and hence is much faster.
IBE Implies Signatures
Various IBE techniques described above can be used to provide public key signature systems and methods. The intuition is as follows. The private key for the signature scheme is the master key for the IBE scheme. The public key for the signature scheme is the set of global system parameters for the IBE scheme. The signature on a message M is the IBE decryption key for ID=M. To verify a signature, choose a random message M′, encrypt M′ using the public key ID=M, and then attempt to decrypt using the given signature on M as the decryption key. If the IBE system is IND-ID-CCA, then the signature scheme is existentially unforgeable against a chosen message attack. Note that, unlike most signature schemes, this signature verification embodiment is randomized. This shows that the IBE techniques described herein may encompass both public key encryption and digital signatures. Signature schemes derived from these approaches can be used to provide interesting properties, as described by Boneh et al. (D. Boneh, B. Lynn, H. Shacham, “Short signatures from the Weil pairing”, in Advances in Cryptology—AsiaCrypt 2001, Lecture Notes in Computer Science, Vol. 2248, Springer-Verlag, pp. 514-532, 2001, which is incorporated herein by reference).
Escrow ElGamal Encryption
In this section we show that various IBE techniques described above can be used to provide an ElGamal encryption system embodiment having global escrow capability. In this embodiment, a single escrow key enables the decryption of ciphertexts encrypted under any public key.
In one exemplary embodiment, the ElGamal escrow system works as follows. The Setup is similar to that for BasicIdent. Unlike the identity-based BasicIdent, each user selects a secret random number and uses it to generate a public/private key pair. A sender and receiver can then use Encrypt and Decrypt to communicate an encrypted message. The message is secure except for an escrow who can use a master key s to decrypt the message.
In more detail, an exemplary embodiment of the technique involves the following procedures:
Another embodiment uses a similar hardness assumption, with an ElGamal encryption system with non-global escrow. In this embodiment, each user constructs a public key with two corresponding private keys, and gives one of the private keys to the trusted third party. The trusted third party maintains a database of all private keys given to it by the various users. Although both private keys can be used to decrypt, only the user's private key can be used simultaneously as the signing key for a discrete logarithm based signature scheme.
Various other cryptographic systems can be devised based on the principles illustrated in the above embodiments. For example, three entities A, B, and C can communicate securely as a group by privately selecting random integers a, b, c and publishing public keys aP, bP, cP. One of them, such as A, could encrypt a message using the message key ê(bP, cP)r and transmit it with rP. Then B could decrypt the message by calculating ê(cP, rP)b and C could decrypt it by calculating ê(bP, rP)c. Similarly, B could send a message to A and C, or C could send a message to A and B.
In another possible embodiment, two of the three entities, say A and B, could publish a joint public key abP. Then C could encrypt a message using the message key ê(abP, cP)r and transmit it with rP. Then neither A nor B alone could decrypt the message, but both A and B together could compute ê(cP, rP)ab and jointly decrypt the message. This technique generalizes to any number of entities. For example, C could join A and B by using abP to compute and publish the three-way joint public key abcP. Then anyone could encrypt a message using the message key ê(abcP, xP)r and transmit it with rP. Then only A and B and C together could compute ê(xP, rP)abc and jointly decrypt the message.
Threshold Decryption.
Embodiments of the invention enable n entities to have shares of a private key dID corresponding to a given public key ID, so that messages encrypted using ID can only be decrypted if t of the n entities collaborate. The private key dID is never reconstructed in a single location. Embodiments of our IBE system may support this as follows.
Recall that in other embodiments the private key dID=sQID where sε*q is the master-key. Instead, let s1, . . . snε*q be a t-out-of-n Shamir secret sharing of the master-key s. Each of the n users is given di=siQID. To decrypt a ciphertext <U, V> encrypted using the key ID each user locally computes gi=ê(U, di) and sends giε2 to the user managing the decryption process. That user then combines the decryption shares by computing gID=
where λi are the appropriate Lagrange interpolation coefficients used in Shamir secret sharing. The message is then obtained by computing H2(gID)⊕V=M.
Those skilled in the art of cryptography will be able to devise many other schemes that employ the basic principles of the present invention.
Applications of Identity-Based Encryption
One application for embodiments of identity-based encryption is to help the deployment of a public key infrastructure. In this section, we show several embodiments of this and other applications.
Revocation of Public Keys
In this embodiment, the sender may encrypt using a public key derived from a piece of information containing a time element, such as a year, date or other time, to help provide key expiration or other forms of temporal key management. For example, in one embodiment, key expiration can be done by having Alice encrypt e-mail sent to Bob using the public key: “bob@company.com ∥ current-year”. In doing so Bob can use his private key during the current year only. Once a year Bob needs to obtain a new private key from the PKG. Hence, we get the effect of annual private key expiration. Note that unlike the existing public key infrastructure, Alice does not need to obtain a new certificate from Bob every time Bob refreshes his private key.
One may make this approach more granular in other embodiments by encrypting e-mail for Bob using “bob@company.com ∥ current-date”, or using another time stamp. This forces Bob to obtain a new private key every day. This embodiment may be used in a corporate context where the PKG is maintained by the corporation. With this approach key revocation is very simple: when Bob leaves the company and his key needs to be revoked, the corporate PKG is instructed to stop issuing private keys for Bob's e-mail address. As a result, Bob can no longer read his email. The interesting property is that Alice does not need to communicate with any third party certificate directory to obtain Bob's daily public key. Hence, embodiments of identity based encryption can provide a very efficient mechanism for implementing ephemeral public keys. Also note that this embodiment can be used to enable Alice to send messages into the future: Bob will only be able to decrypt the e-mail on the date specified by Alice.
Managing User Credentials
An embodiment of the invention enables the management of user credentials using an IBE system. The message is encrypted with a string containing a credential identifier. For example, suppose Alice encrypts mail to Bob using the public key: “bob@company.com ∥ current-year ∥ clearance=secret”. Then Bob will only be able to read the email if on the specified date he has secret clearance. Consequently, it is very easy to grant and revoke user credentials using the PKG.
Sender system 1001 encrypts a message M using encryption logic 1004 in plug-in 1017. Encryption logic 1004 encrypts the message using encryption key 1011, which is based on selected credential 1005 and an identification 1016 of the intended receiver of the message. In some embodiments, the key may be based on other information as well. The sender system 1001 sends the receiver system 1002 information 1006, e.g., in the form of a data packet transmitted over a network or other communication medium. The information 1006 sent to receiver system 1002 contains the encrypted message and may also contain information 1007 regarding the credential 1005 used as part of the basis for the encryption key.
Either before or after receiving information 1006, receiver system 1002 sends a request 1009 to PKG 1003. In one embodiment, the request 1009 may include the receiver's identity 1016 and may also include information related to the selected credential 1005. In response, PKG 1003 verifies the credential of receiver 1002 using credential check logic 1008. Such logic may be implemented in software, hardware or a combination thereof. If the credential is verified as belonging to the receiver, then PKG 1003 provides a response 1010 to receiver 1002, which includes a private decryption key 1018 corresponding to the encryption key 1011. Using the private decryption key, the receiver then may decrypt the encrypted message contained in information 1006 to recover the original message M. Thus, by including a credential as part of an encryption key, embodiments such as this one allow a sender to encrypt a message intended for a receiver, where the decryption of the message by the receiver is contingent upon the validity of the receiver's credential.
Delegation of Decryption Keys
Another application for embodiments of IBE systems is delegation of decryption capabilities. We give two exemplary embodiments, described with reference to a user Bob who plays the role of the PKG. Bob runs the setup algorithm to generate his own IBE system parameters params and his own master-key. Here we view params as Bob's public key. Bob obtains a certificate from a CA for his public key params. When Alice wishes to send mail to Bob she first obtains Bob's public key params from Bob's public key certificate. Note that Bob is the only one who knows his master-key and hence there is no key-escrow with this setup.
An embodiment of a system having return receipt capability is illustrated in
The sender 1201 encrypts a message M and sends the resulting ciphertext to receiver 1202 in a data package 1204 that also may include return receipt request information 1209. The return receipt request information may contain, for example, a return address and a message identifier corresponding to the particular message 1204. The message M is encrypted by the sender using encryption logic 1211 and an encryption key 1215. Encryption key 1215 may be based on a receiver ID (such as an e-mail address) 1216 and the return receipt request information 1209. Because the receiver ID and return receipt request information 1209 are used by the sender to determine the encryption key 1215, the receiver 1202 needs a corresponding decryption key that can be used to decrypt the message. Accordingly, recipient system 1202, in response to receiving message 1204, sends PKG 1203 a request 1206, which includes the return receipt request information 1209 and the receiver's ID, 1216. In response, PKG 1203 sends to receiver 1202 the private decryption key 1205, which receiver then uses with decryption logic 1217 to decrypt the ciphertext of message 1204 and recover the original message M. In addition to sending receiver 1202 the decryption key 1205, PKG 1203 also sends a return receipt 1207 to sender 1201. PKG 1203 may alternatively store the receipt on storage media as part of a log rather than send a return receipt. Return receipt 1207 may include information such as the message identifier. Thus, sender 1201 receives proof that recipient 1202 has received the message 1204. The system may be initialized by placing plug-in software in various systems, such as sender system 1201 and receiver system 1202. Such plug-in software may include system parameters, some of which may be derived from a system master key. Such parameters, stored in local devices such as sender 1201 and receiver 1202 are then used to generate encryption keys, perform encryption, perform decryption, and other functions, as appropriate.
Description of the Weil Pairing
In this section we describe the Weil pairing on elliptic curves and then show how to efficiently compute it using an algorithm. To be concrete we present an example using supersingular elliptic curves defined over a prime field p with p>3 (the curve y2=x3+1 over p with p=2 mod 3 is an example of such a curve). The following discussion easily generalizes to computing the Weil pairing over other elliptic curves.
Elliptic Curves and the Weil Pairing
We state a few elementary facts about supersingular elliptic curves defined over a prime field p with p>3:
We briefly show that the Weil pairing is well defined. That is, the value of e(P, Q) is independent of the choice of the divisor P as long as P is equivalent to (P)−(O) and P leads to a well defined value. The same holds for Q. Let {circumflex over ()}P be a divisor equivalent to P and let {circumflex over (ƒ)}P be a function so that ({circumflex over (ƒ)}P)=n{circumflex over ()}P. Then {circumflex over ()}P=P+(g) for some function g and {circumflex over (ƒ)}P=ƒP·gn. We have that:
The last equality follows from the following fact known as Weil reciprocity: for any two functions ƒ, g we have that ƒ((g))=g((ƒ)). Hence, the Weil pairing is well defined.
Fact 10 The Weil pairing has the following properties:
As discussed earlier, our detailed example of an embodiment of an IBE scheme uses the modified Weil pairing ê(P, Q)=e(P, φ(Q)), where φ is an automorphism on the group of points of E.
Tate pairing. The Tate pairing is another bilinear pairing that has the required properties for embodiments of our system. In various embodiments, we slightly modify the original definition of the Tate pairing to fit our purpose. Define the Tate pairing of two points P, QεE[n] as
where ƒP and Q are defined as earlier. This definition gives a computable bilinear pairing T: E[n]×E[n]→2.
Computing the Weil Pairing
Given two points P, QεE[n] we show how to compute e(P, Q)ε*p
This expression is well defined with very high probability over the choice of R1, R2 (the probability of failure is at most
In the rare event that a division by zero occurs during the computation of e(P, Q) we simply pick new random points R1, R2 and repeat the process.
To evaluate e(P, Q) it suffices to show how to evaluate the function ƒP at Q. Evaluating ƒQ(P) is done analogously. We evaluate ƒP(Q) using repeated doubling. For a positive integer b define the divisor
b=b(P+R1)−b(R1)−(bP)+(O)
It is a principal divisor and therefore there exists a function ƒb such that (ƒb)=b. Observe that (ƒP)=(ƒn) and hence, ƒP(Q)=ƒn(Q). It suffices to show how to evaluate ƒn(Q).
Lemma 11 There is an algorithm that given ƒb(Q), ƒc(Q) and bP, cP, (b+c)P for some b, c>0 outputs ƒb+c(Q). The algorithm only uses a (small) constant number of arithmetic operations in p
Proof We first define two auxiliary linear functions g1, g2:
Denote the output of Algorithm of Lemma 11 by (ƒb(Q), ƒc(Q), bP, cP, (b+c)P)=ƒb+c(Q). Then one can compute ƒP(Q)=ƒn(Q) using the following standard repeated doubling procedure. Let n=bmbm-1 . . . b1b0 be the binary representation of n, i.e.
Init: Set Z=O, V=ƒ0(Q)=1, and k=0.
Iterate: For i=m, m−1, . . . , 1, 0 do:
This application is a continuation of copending U.S. patent application Ser. No. 10/218,691 filed Aug. 13, 2002, which claims the benefit of U.S. provisional application No. 60/311,946, filed Aug. 13, 2001, both of which are incorporated herein by reference.
The present invention was made with the support of DARPA contract F30602-99-1-0530. The U.S. Government has certain rights in the invention.
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20070041583 A1 | Feb 2007 | US |
Number | Date | Country | |
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60311946 | Aug 2001 | US |
Number | Date | Country | |
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Parent | 10218697 | Aug 2002 | US |
Child | 11431410 | May 2006 | US |