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Lecture10 – More on Physically Unclonable Functions (PUFs)

Lecture10 – More on Physically Unclonable Functions (PUFs). Rice ELEC 528/ COMP 538 Farinaz Koushanfar Spring 2009. Outline. Implementations on silicon Applications Cryptographic keys Authentication Details of RFID applications Issues with nonstability. Tamper-Proof Package: IBM 4758.

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Lecture10 – More on Physically Unclonable Functions (PUFs)

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  1. Lecture10 – More on Physically Unclonable Functions (PUFs) Rice ELEC 528/ COMP 538 Farinaz Koushanfar Spring 2009

  2. Outline • Implementations on silicon • Applications • Cryptographic keys • Authentication • Details of RFID applications • Issues with nonstability

  3. Tamper-Proof Package: IBM 4758 Sensors to detect attacks Expensive Continually battery-powered Trusted Platform Module (TPM) A separate chip (TPM) for security functions Decrypted “secondary” keys can be read out from the bus Existing Approaches

  4. EEPROM/ROM Probe Processor Problem Storing digital information in a device in a way that is resistant to physical attacks is difficult and expensive. • Adversaries can physically extract secret keys from EEPROM while processor is off • Trusted party must embed and test secret keys in a secure location • EEPROM adds additional complexity to manufacturing

  5. Physical System Processor Our Solution:Physical Random Functions (PUFs) • Generate keys from a complex physical system Hard to fully characterize or predict characterize configure Use as a secret Response (n-bits) Can generate many secrets by changing the challenge Challenge (c-bits) • Security Advantage • Keys are generated on demand  No non-volatile secrets • No need to program the secret • Can generate multiple master keys • What can be hard to predict, but easy to measure?

  6. PUF Experiments • Fabricated 200 “identical” chips with PUFs in TSMC 0.18m on 5 different wafer runs • Security • What is the probability that a challenge produces different responses on two different PUFs? • Reliability • What is the probability that a PUF output for a challenge changes with temperature? • With voltage variation?

  7. Measurement noise for Chip X = 0.9 bits Distance between Chip X and Y responses = 24.8 bits Inter-Chip Variation • Apply random challenges and observe 100 response bits Can identify individual ICs

  8. Measurement noise with 10% voltage variation = 4 bits Environmental Variations • What happens if we change voltage and temperature? Measurement noise at 125C (baseline at 20C) = 3.5 bits Even with environmental variation, we can still distinguish two different PUFs

  9. New Response One-Way Hash Function BCH Decoding k Syndrome BCH Encoding n - k Syndrome Reliable PUFs PUFs can be made more secure and reliable by adding extra control logic Challenge Response PUF c n For Re-generation For calibration • Hash function (SHA-1,MD5) precludes PUF “model-building” attacks since, to obtain PUF output, adversary has to invert a one-way function • Error Correcting Code (ECC) can eliminate the measurement noise without compromising security

  10. Ring-Oscillator (RO) PUF • The structure relies on delay loops and counters instead of MUX and arbiters • Better results on FPGA – more stable

  11. RO PUFs (cont’d) • Easy to duplicate a ring oscillator and make sure the oscillators are identical • Much easier than ensuring the racing paths with equal path segments • How many bits can we generate from the scheme in the previous page? • There are N(N-1)/2 distinct pairs, but the entropy is significantly smaller: log2(N!) • E.g., 35 ROs can produce 133 bits, 128 can produce 716, and 1024 can produce 8769

  12. Reliability enhancement • Environmental changes have a large impact on the freq. (and even relative ones)

  13. RO PUFs • ROs whose frequencies are far are more stable than the ones with closer f’s • Possible advantage: do not use all pairs, but only the stable ones • It is easy to watch the distance in the counter and pick the very different ones • The new question is how many ring oscillators do we need to accomplish having B stable bits? • What are the other comparative advantages/ disadvantages compared to delay-based PUFs? • Can we use this structure to generate many challenge-response pairs?

  14. Applications -- Authentication • Challenges should never be used to prevent the man-in-the-middle attacks • Is this practical?

  15. Application – Cryptographic Key Generation • The unstability is a problem • Some crypto protocols (e.g., RSA) require specific mathematical properties that random numbers generated by PUFs do not have • How can we use PUFs to generate crypto keys? • Error correction process: initialization and regeneration • There should be a one-way function that can generate the key from the PUF output

  16. Crypto Key Generation • Initialization: a PUF output is generated and error correcting code (e.g., BCH) computes the syndrome (public info) • Regeneration: PUF uses the syndrome from the initial phase to correct changes in the output • Clearly, the syndrome reveals information about the circuit output and introduces vulnerabilities

  17. Vulnerabilities Caused by ECC • Given a b-bit syndrome, the attackers can learn at most b-bits about the PUF output • Thus, to have k secret bits after error correction, we generate n=k+b bits at PUF • How much area / power overhead do we get for the RO implementation?

  18. Experiments with RO PUFs • Experiments done on 15 Xilinx Virtex4 LX25 FPGA (90nm) • They placed 1024 ROs in each FPGA as a 16-by-64 array • Each RO consisted of 5 INVs and 1 AND, implemented using look-up tables • The goal is to know if the PUF outputs are unique (for security) and reproducible (for reliability and security)

  19. Reliability and Security Metrics

  20. The Probability Distribution for Inter-chip Variations • 128 bits are produced from each PUF • x-axis: number of PUF o/p bits different b/w two FPGAs; y-axis: probability • Purple bars show the results from 105 pair-wise comparisons • Blue lines show a binomial distribution with fitted parameters (n=128, p =0.4615) • Average intra-chip variations 0.4615 ~ 0.5

  21. The Probability Distribution for Intra-chip Variations • PUF o/p are generated at two different conditions and compared • Changing the temperature from 20C to 120C and the core voltage from 1.2 to 1.08 altered the PUF o/p by ~0.6 bits (0.48%) • Intra-chip variations is much lower than inter-chip – the PUF o/p did not change fro small to moderate environmental changes

  22. False Positive (FP) and Negative (FN) Experiments • If we allow up to 10 bits out of 128 to be different, FP rate ~2.1x10-21, and FN rate is less than 5x10-11 • Assumption: inter-chip and intra-chip follow binomial distributions • The same experiments could be used to compute the reliability of PUF-based crypto keys

  23. Physically Unclonable Function–Based Security and Privacy in RFID Systems Leonid Bolotnyy and Gabriel Robins Dept. of Computer Science University of Virginia www.cs.virginia.edu/robins

  24. Contribution and Motivation Contribution • Privacy-preserving tag identification algorithm • Secure MAC algorithms • Comparison of PUF with digital hash functions Motivation • Digital crypto implementations require 1000’s of gates • Low-cost alternatives • Pseudonyms / one-time pads • Low complexity / power hash function designs • Hardware-based solutions

  25. PUF-Based Security • Physical Unclonable Function (PUF) [Gassend et al 2002] • PUF Security is based on • wire delays • gate delays • quantum mechanical fluctuations • PUF characteristics • uniqueness • reliability • unpredictability • PUF Assumptions • Infeasible to accurately model PUF • Pair-wise PUF output-collision probability is constant • Physical tampering will modify PUF

  26. privacy Privacy in RFID • Privacy A B C Alice was here: A, B, C

  27. Database ID1, p(ID1), p2(ID1), …, pk(ID1) ... IDn, pn(IDn), pn2(IDn), …, pnk(IDn) ID Request Private Identification Algorithm ID p(ID) • It is important to have • a reliable PUF • no loops in PUF chains • no identical PUF outputs • Assumptions • no denial of service attacks (e.g., passive adversaries, DoS detection/prevention mechanisms) • physical compromise of tags not possible

  28. number of runs unreliability probability chain length N μm(1-μ)N-m )k R(μ, N, k)≥ (1 -∑ overall reliability R(0.02, 5, 100) ≥ 0.992 ∞ tuple size expected numberof identifications S(μ, q) = ∑ i [(1 – (1-μ)i+1)q -(1 – (1-μ)i)q] N+1 2 N m i=1 m= S(0.02, 1) = 49, S(0.02, 2) = 73, S(0.02, 3) = 90 Improving Reliability of Responses • Run PUF multiple times for same ID & pick majority • Create tuples of multi-PUF computed IDs &identify a tag based on at least one valid position value (ID1, ID2, ID3)

  29. Privacy Model Experiment: • A passive adversary observes polynomially-many rounds of reader-tag communications with multiple tags • An adversary selects 2 tags • The reader randomly and privately selects one of the 2 tags and runs one identification round with the selected tag • An adversary determines the tag that the reader selected Definition: The algorithm is privacy-preserving if an adversary can notdetermine reader selected tag with probability substantially greater than ½ Theorem: Given random oracle assumption for PUFs, an adversary has no advantage in the above experiment.

  30. valid signature σ: υ (M, σ) = 1 K • forged signature σ’ : υ (M’, σ’) = 1, M = M’ K PUF-Based MAC Algorithms • MAC = (K, τ, υ) • MAC based on PUF • Motivation: “yoking-proofs”, signing sensor data • large keys (PUF is the key) • cannot support arbitrary messages • Assumptions • adversary can adaptively learn poly-many (m, σ) pairs • signature verifiers are off-line • tag can store a counter (to protect against replay attacks)

  31. Large Message Space Assumption: tag can generate good random numbers (can be PUF-based) Key: PUF σ (m) =c, r1, ..., rn, pc(r1, m), ..., pc(rn, m) • Signature verification • requires tag’s presence • password-based or in radio-protected environment (Faraday Cage) • learn pc(ri, m), 1 ≤ i ≤ n • verify that the desired fraction of PUF computations is correct • To protect against hardware tampering • authenticate tag before MAC verification • store verification password underneath PUF

  32. n n i n j probv(n, t, μ)= 1 -∑ μi(1-μ)n-i i=t+1 n probf(n, t, τ)= 1 -∑ τj(1-τ)n-j j=t+1 α < probv ≤ 1 and probf ≤ β ≤ 1 0 ≤ t ≤ n-1 Choosing # of PUF Computations probv(n, 0.1n, 0.02) probf(n, 0.1n, 0.4)

  33. Theorem Given random oracle assumption for a PUF, the probability that an adversary could forge a signature for a message is bounded from above by the tag impersonation probability.

  34. message counter PUF Key[p, mi, c] = c, pc(1)(mi), ..., pc(n) (mi) σ(m) =c, pc(1)(m), ..., pc(n)(m), ..., c+q-1, pc+q-1(1)(m), pc+q-1(n)(m) sub-signature Small Message Space Assumption: small and known a priori message space PUF reliability is again crucial Verify that the desired number of sub-signatures are valid

  35. Theorem Given random oracle assumption for a PUF, the probability that an adversary could forge a signature for a message is bounded by the tag impersonation probability times the number of sub-signatures.

  36. original clone • Impersonation attacks • manufacture an identical tag • obtain (steal) existing PUFs • Modeling attacks • build a PUF model to predict PUF’s outputs • Side-channel attacks • algorithm timing • power consumption • Hardware-tampering attacks • physically probe wires to learn the PUF • physically read-off/alter keys/passwords Attacks on MAC Protocols

  37. algorithm # of gates MD4 MD5 SHA-256 AES Yuksel PUF 7350 8400 10868 3400 1701 545 Comparison of PUF With Digital Hash Functions • Reference PUF: 545 gates for 64-bit input • 6 to 8 gates for each input bit • 33 gates to measure the delay • Low gate count of PUF has a cost • probabilistic outputs • difficult to characterize analytically • non-unique computation • extra back-end storage • Different attack target for adversaries • model building rather than key discovery • Physical security • hard to break tag and remain undetected

  38. PUF Design • Attacks on PUF • impersonation • modeling • hardware tampering • side-channel • Weaknesses of existing PUF reliability • New PUF design • no oscillating circuit • sub-threshold voltage • Compare different non-linear delay approaches

  39. } in progress Conclusions and Future Work • PUF: hardware primitive for RFID security • Identification and MAC algorithms based on PUF • PUFs protect tags from physical attacks • PUFs is the key • Develop theoretical framework for PUF • Design new sub-threshold voltage based PUF • Manufacture and test PUFs • varying environmental conditions • motion, acceleration, vibration, temperature, noise • Design new PUF-based security protocols • ownership transfer • recovery from privacy compromise • PUFs on RFID readers

  40. Thank You Questions ? Leonid Bolotnyy lbol@cs.virginia.edu Dept. of Computer Science University of Virginia

  41. PUF-Based Ownership Transfer • Ownership Transfer • To maintain privacy we need • ownership privacy • forward privacy • Physical security is especially important • Solutions • public key cryptography (expensive) • knowledge of owners sequence • trusted authority • short period of privacy

  42. s1,2 s2,4 s2,5 s3,8 s3,9 s3,10 Using PUF to Detect and Restore Privacy of Compromised System s1,0 s1,1 s2,0 s2,1 s2,2 s2,3 s3,0 s3,1 s3,2 s3,3 s3,4 s3,5 s3,6 s3,7 • Detect potential tag compromise • Update secrets of affected tags

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