Your search keyword '"Duffy, Ken R."' showing total 584 results

1. Error correction in interference-limited wireless systems

Author

Wiame, Charles, Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing

Abstract

We introduce a novel approach to error correction decoding in the presence of additive alpha-stable noise, which serves as a model of interference-limited wireless systems. In the absence of modifications to decoding algorithms, treating alpha-stable distributions as Gaussian results in significant performance loss. Building on Guessing Random Additive Noise Decoding (GRAND), we consider two approaches. The first accounts for alpha-stable noise in the evaluation of log-likelihood ratios (LLRs) that serve as input to Ordered Reliability Bits GRAND (ORBGRAND). The second builds on an ORBGRAND variant that was originally designed to account for jamming that treats outlying LLRs as erasures. This results in a hybrid error and erasure correcting decoder that corrects errors via ORBGRAND and corrects erasures via Gaussian elimination. The block error rate (BLER) performance of both approaches are similar. Both outperform decoding assuming that the LLRs originated from Gaussian noise by 2 to 3 dB for [128,112] 5G NR CA-Polar and CRC codes.

Published

2024

2. Soft-output Guessing Codeword Decoding

Author

Duffy, Ken R., Yuan, Peihong, Griffin, Joseph, and Medard, Muriel

Subjects

Computer Science - Information Theory

Abstract

We establish that it is possible to extract accurate blockwise and bitwise soft output from Guessing Codeword Decoding with minimal additional computational complexity by considering it as a variant of Guessing Random Additive Noise Decoding. Blockwise soft output can be used to control decoding misdetection rate while bitwise soft output results in a soft-input soft-output decoder that can be used for efficient iterative decoding of long, high redundancy codes.

Published

2024

3. Leveraging AES Padding: dBs for Nothing and FEC for Free in IoT Systems

Author

Woo, Jongchan, Vasudevan, Vipindev Adat, Kim, Benjamin D., D'Oliveira, Rafael G. L., Cohen, Alejandro, Stahlbuhk, Thomas, Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Emerging Technologies, Computer Science - Hardware Architecture, Electrical Engineering and Systems Science - Systems and Control

Abstract

The Internet of Things (IoT) represents a significant advancement in digital technology, with its rapidly growing network of interconnected devices. This expansion, however, brings forth critical challenges in data security and reliability, especially under the threat of increasing cyber vulnerabilities. Addressing the security concerns, the Advanced Encryption Standard (AES) is commonly employed for secure encryption in IoT systems. Our study explores an innovative use of AES, by repurposing AES padding bits for error correction and thus introducing a dual-functional method that seamlessly integrates error-correcting capabilities into the standard encryption process. The integration of the state-of-the-art Guessing Random Additive Noise Decoder (GRAND) in the receiver's architecture facilitates the joint decoding and decryption process. This strategic approach not only preserves the existing structure of the transmitter but also significantly enhances communication reliability in noisy environments, achieving a notable over 3 dB gain in Block Error Rate (BLER). Remarkably, this enhanced performance comes with a minimal power overhead at the receiver - less than 15% compared to the traditional decryption-only process, underscoring the efficiency of our hardware design for IoT applications. This paper discusses a comprehensive analysis of our approach, particularly in energy efficiency and system performance, presenting a novel and practical solution for reliable IoT communications.

Published

2024

4. Near-Optimal Generalized Decoding of Polar-like Codes

Author

Yuan, Peihong, Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Information Theory

Abstract

We present a framework that can exploit the tradeoff between the undetected error rate (UER) and block error rate (BLER) of polar-like codes. It is compatible with all successive cancellation (SC)-based decoding methods and relies on a novel approximation that we call codebook probability. This approximation is based on an auxiliary distribution that mimics the dynamics of decoding algorithms following an SC decoding schedule. Simulation results demonstrates that, in the case of SC list (SCL) decoding, the proposed framework outperforms the state-of-art approximations from Forney's generalized decoding rule for polar-like codes with dynamic frozen bits. In addition, dynamic Reed-Muller (RM) codes using the proposed generalized decoding significantly outperform CRC-concatenated polar codes decoded using SCL in both BLER and UER. Finally, we briefly discuss three potential applications of the approximated codebook probability: coded pilot-free channel estimation; bitwise soft-output decoding; and improved turbo product decoding., Comment: being published at IEEE ISIT 2024

Published

2024

5. Soft-output (SO) GRAND and Iterative Decoding to Outperform LDPCs

Author

Yuan, Peihong, Medard, Muriel, Galligan, Kevin, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

We establish that a large, flexible class of long, high redundancy error correcting codes can be efficiently and accurately decoded with guessing random additive noise decoding (GRAND). Performance evaluation demonstrates that it is possible to construct simple concatenated codes that outperform low-density parity-check (LDPC) codes found in the 5G New Radio standard in both additive white Gaussian noise (AWGN) and fading channels. The concatenated structure enables many desirable features, including: low-complexity hardware-friendly encoding and decoding; significant flexibility in length and rate through modularity; and high levels of parallelism in encoding and decoding that enable low latency. Central is the development of a method through which any soft-input (SI) GRAND algorithm can provide soft-output (SO) in the form of an accurate a-posteriori estimate of the likelihood that a decoding is correct or, in the case of list decoding, the likelihood that each element of the list is correct. The distinguishing feature of soft-output GRAND (SOGRAND) is the provision of an estimate that the correct decoding has not been found, even when providing a single decoding. That per-block SO can be converted into accurate per-bit SO by a weighted sum that includes a term for the SI. Implementing SOGRAND adds negligible computation and memory to the existing decoding process, and using it results in a practical, low-latency alternative to LDPC codes., Comment: arXiv admin note: substantial text overlap with arXiv:2305.05777

Published

2023

6. Almost sure one-endedness of a random graph model of distributed ledgers

Author

Feng, Jiewei, King, Christopher, and Duffy, Ken R.

Subjects

Mathematics - Probability, Mathematics - Dynamical Systems

Abstract

Blockchain and other decentralized databases, known as distributed ledgers, are designed to store information online where all trusted network members can update the data with transparency. The dynamics of ledger's development can be mathematically represented by a directed acyclic graph (DAG). One essential property of a properly functioning shared ledger is that all network members holding a copy of the ledger agree on a sequence of information added to the ledger, which is referred to as consensus and is known to be related to a structural property of DAG called one-endedness. In this paper, we consider a model of distributed ledger with sequential stochastic arrivals that mimic attachment rules from the IOTA cryptocurrency. We first prove that the number of leaves in the random DAG is bounded by a constant infinitely often through the identification of a suitable martingale, and then prove that a sequence of specific events happens infinitely often. Combining those results we establish that, as time goes to infinity, the IOTA DAG is almost surely one-ended., Comment: 28 pages, updated information for authors

Published

2023

7. Upgrade error detection to prediction with GRAND

Author

Galligan, Kevin, Yuan, Peihong, Médard, Muriel, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

Guessing Random Additive Noise Decoding (GRAND) is a family of hard- and soft-detection error correction decoding algorithms that provide accurate decoding of any moderate redundancy code of any length. Here we establish a method through which any soft-input GRAND algorithm can provide soft output in the form of an accurate a posteriori estimate of the likelihood that a decoding is correct or, in the case of list decoding, the likelihood that the correct decoding is an element of the list. Implementing the method adds negligible additional computation and memory to the existing decoding process. The output permits tuning the balance between undetected errors and block errors for arbitrary moderate redundancy codes including CRCs

Published

2023

8. PEOPL: Characterizing Privately Encoded Open Datasets with Public Labels

Author

Esfahanizadeh, Homa, Yala, Adam, D'Oliveira, Rafael G. L., Jaba, Andrea J. D., Quach, Victor, Duffy, Ken R., Jaakkola, Tommi S., Vaikuntanathan, Vinod, Ghobadi, Manya, Barzilay, Regina, and Médard, Muriel

Subjects

Computer Science - Machine Learning, Computer Science - Cryptography and Security, Computer Science - Information Theory

Abstract

Allowing organizations to share their data for training of machine learning (ML) models without unintended information leakage is an open problem in practice. A promising technique for this still-open problem is to train models on the encoded data. Our approach, called Privately Encoded Open Datasets with Public Labels (PEOPL), uses a certain class of randomly constructed transforms to encode sensitive data. Organizations publish their randomly encoded data and associated raw labels for ML training, where training is done without knowledge of the encoding realization. We investigate several important aspects of this problem: We introduce information-theoretic scores for privacy and utility, which quantify the average performance of an unfaithful user (e.g., adversary) and a faithful user (e.g., model developer) that have access to the published encoded data. We then theoretically characterize primitives in building families of encoding schemes that motivate the use of random deep neural networks. Empirically, we compare the performance of our randomized encoding scheme and a linear scheme to a suite of computational attacks, and we also show that our scheme achieves competitive prediction accuracy to raw-sample baselines. Moreover, we demonstrate that multiple institutions, using independent random encoders, can collaborate to train improved ML models., Comment: Submitted to IEEE Transactions on Information Forensics and Security

Published

2023

9. Using channel correlation to improve decoding -- ORBGRAND-AI

Author

Duffy, Ken R., Grundei, Moritz, and Medard, Muriel

Subjects

Computer Science - Information Theory

Abstract

To meet the Ultra Reliable Low Latency Communication (URLLC) needs of modern applications, there have been significant advances in the development of short error correction codes and corresponding soft detection decoders. A substantial hindrance to delivering low-latency is, however, the reliance on interleaving to break up omnipresent channel correlations to ensure that decoder input matches decoder assumptions. Consequently, even when using short codes, the need to wait to interleave data at the sender and de-interleave at the receiver results in significant latency that acts contrary to the goals of URLLC. Moreover, interleaving reduces channel capacity, so that potential decoding performance is degraded. Here we introduce a variant of Ordered Reliability Bits Guessing Random Additive Noise Decoding (ORBGRAND), which we call ORBGRAND-Approximate Independence (ORBGRAND-AI), a soft-detection decoder that can decode any moderate redundancy code and overcomes the limitation of existing decoding paradigms by leveraging channel correlations and circumventing the need for interleaving. By leveraging correlation, not only is latency reduced, but error correction performance can be enhanced by multiple dB, while decoding complexity is also reduced, offering one potential solution for the provision of URLLC.

Published

2023

10. GRAND-EDGE: A Universal, Jamming-resilient Algorithm with Error-and-Erasure Decoding

Author

Ercan, Furkan, Galligan, Kevin, Starobinski, David, Medard, Muriel, Duffy, Ken R., and Yazicigil, Rabia Tugce

Subjects

Computer Science - Information Theory

Abstract

Random jammers that overpower transmitted signals are a practical concern for many wireless communication protocols. As such, wireless receivers must be able to cope with standard channel noise and jamming (intentional or unintentional). To address this challenge, we propose a novel method to augment the resilience of the recent family of universal error-correcting GRAND algorithms. This method, called Erasure Decoding by Gaussian Elimination (EDGE), impacts the syndrome check block and is applicable to any variant of GRAND. We show that the proposed EDGE method naturally reverts to the original syndrome check function in the absence of erasures caused by jamming. We demonstrate this by implementing and evaluating GRAND-EDGE and ORBGRAND-EDGE. Simulation results, using a Random Linear Code (RLC) with a code rate of $105/128$, show that the EDGE variants lower both the Block Error Rate (BLER) and the computational complexity by up to five order of magnitude compared to the original GRAND and ORBGRAND algorithms. We further compare ORBGRAND-EDGE to Ordered Statistics Decoding (OSD), and demonstrate an improvement of up to three orders of magnitude in the BLER., Comment: 7 pages, 7 figures, accepted for IEEE ICC 2023 conference

Published

2023

11. Soft detection physical layer insecurity

Author

Duffy, Ken R. and Medard, Muriel

Subjects

Computer Science - Information Theory

Abstract

We establish that during the execution of any Guessing Random Additive Noise Decoding (GRAND) algorithm, an interpretable, useful measure of decoding confidence can be evaluated. This measure takes the form of a log-likelihood ratio (LLR) of the hypotheses that, should a decoding be found by a given query, the decoding is correct versus its being incorrect. That LLR can be used as soft output for a range of applications and we demonstrate its utility by showing that it can be used to confidently discard likely erroneous decodings in favor of returning more readily managed erasures. We show that feature can be used to compromise the physical layer security of short length wiretap codes by accurately and confidently revealing a proportion of a communication when code-rate is far above the Shannon capacity of the associated hard detection channel.

Published

2022

12. Physical layer insecurity

Author

Médard, Muriel and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

In the classic wiretap model, Alice wishes to reliably communicate to Bob without being overheard by Eve who is eavesdropping over a degraded channel. Systems for achieving that physical layer security often rely on an error correction code whose rate is below the Shannon capacity of Alice and Bob's channel, so Bob can reliably decode, but above Alice and Eve's, so Eve cannot reliably decode. For the finite block length regime, several metrics have been proposed to characterise information leakage. Here we assess a new metric, the success exponent, and demonstrate it can be operationalized through the use of Guessing Random Additive Noise Decoding (GRAND) to compromise the physical-layer security of any moderate length code. Success exponents are the natural beyond-capacity analogue of error exponents that characterise the probability that a maximum likelihood decoding is correct when the code-rate is above Shannon capacity, which is exponentially decaying in the code-length. Success exponents can be used to approximately evaluate the frequency with which Eve's decoding is correct in beyond-capacity channel conditions. Through the use of GRAND, we demonstrate that Eve can constrain her decoding procedure so that when she does identify a decoding, it is correct with high likelihood, significantly compromising Alice and Bob's communication by truthfully revealing a proportion of it. We provide general mathematical expressions for the determination of success exponents as well as for the evaluation of Eve's query number threshold, using the binary symmetric channel as a worked example. As GRAND algorithms are code-book agnostic and can decode any code structure, we provide empirical results for Random Linear Codes as exemplars. Simulation results demonstrate the practical possibility of compromising physical layer security.

Published

2022

13. A General Security Approach for Soft-information Decoding against Smart Bursty Jammers

Author

Ercan, Furkan, Galligan, Kevin, Duffy, Ken R., Medard, Muriel, Starobinski, David, and Yazicigil, Rabia Tugce

Subjects

Computer Science - Information Theory, Computer Science - Cryptography and Security

Abstract

Malicious attacks such as jamming can cause significant disruption or complete denial of service (DoS) to wireless communication protocols. Moreover, jamming devices are getting smarter, making them difficult to detect. Forward error correction, which adds redundancy to data, is commonly deployed to protect communications against the deleterious effects of channel noise. Soft-information error correction decoders obtain reliability information from the receiver to inform their decoding, but in the presence of a jammer such information is misleading and results in degraded error correction performance. As decoders assume noise occurs independently to each bit, a bursty jammer will lead to greater degradation in performance than a non-bursty one. Here we establish, however, that such temporal dependencies can aid inferences on which bits have been subjected to jamming, thus enabling counter-measures. In particular, we introduce a pre-decoding processing step that updates log-likelihood ratio (LLR) reliability information to reflect inferences in the presence of a jammer, enabling improved decoding performance for any soft detection decoder. The proposed method requires no alteration to the decoding algorithm. Simulation results show that the method correctly infers a significant proportion of jamming in any received frame. Results with one particular decoding algorithm, the recently introduced ORBGRAND, show that the proposed method reduces the block-error rate (BLER) by an order of magnitude for a selection of codes, and prevents complete DoS at the receiver., Comment: Accepted for GLOBECOM 2022 Workshops. Contains 7 pages and 7 figures

Published

2022

14. Soft decoding without soft demapping with ORBGRAND

Author

An, Wei, Medard, Muriel, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

For spectral efficiency, higher order modulation symbols confer information on more than one bit. As soft detection forward error correction decoders assume the availability of information at binary granularity, however, soft demappers are required to compute per-bit reliabilities from complex-valued signals. Here we show that the recently introduced universal soft detection decoder ORBGRAND can be adapted to work with symbol-level soft information, obviating the need for energy expensive soft demapping. We establish that doing so reduces complexity while retaining the error correction performance achieved with the optimal demapper.

Published

2022

15. Block turbo decoding with ORBGRAND

Author

Galligan, Kevin, Médard, Muriel, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

Guessing Random Additive Noise Decoding (GRAND) is a family of universal decoding algorithms suitable for decoding any moderate redundancy code of any length. We establish that, through the use of list decoding, soft-input variants of GRAND can replace the Chase algorithm as the component decoder in the turbo decoding of product codes. In addition to being able to decode arbitrary product codes, rather than just those with dedicated hard-input component code decoders, results show that ORBGRAND achieves a coding gain of up to 0.7dB over the Chase algorithm with same list size.

Published

2022

16. GRAND for Fading Channels using Pseudo-soft Information

Author

Sarieddeen, Hadi, Médard, Muriel, and Duffy, Ken. R.

Subjects

Computer Science - Information Theory

Abstract

Guessing random additive noise decoding (GRAND) is a universal maximum-likelihood decoder that recovers code-words by guessing rank-ordered putative noise sequences and inverting their effect until one or more valid code-words are obtained. This work explores how GRAND can leverage additive-noise statistics and channel-state information in fading channels. Instead of computing per-bit reliability information in detectors and passing this information to the decoder, we propose leveraging the colored noise statistics following channel equalization as pseudo-soft information for sorting noise sequences. We investigate the efficacy of pseudo-soft information extracted from linear zero-forcing and minimum mean square error equalization when fed to a hardware-friendly soft-GRAND (ORBGRAND). We demonstrate that the proposed pseudo-soft GRAND schemes approximate the performance of state-of-the-art decoders of CA-Polar and BCH codes that avail of complete soft information. Compared to hard-GRAND, pseudo-soft ORBGRAND introduces up to 10dB SNR gains for a target 10^-3 block-error rate., Comment: To appear in the IEEE GLOBECOM 2022 proceedings. arXiv admin note: text overlap with arXiv:2207.10836

Published

2022

17. Soft-input, soft-output joint detection and GRAND

Author

Sarieddeen, Hadi, Médard, Muriel, and Duffy, Ken. R.

Subjects

Computer Science - Information Theory

Abstract

Guessing random additive noise decoding (GRAND) is a maximum likelihood (ML) decoding method that identifies the noise effects corrupting code-words of arbitrary code-books. In a joint detection and decoding framework, this work demonstrates how GRAND can leverage crude soft information in received symbols and channel state information to generate, through guesswork, soft bit reliability outputs in log-likelihood ratios (LLRs). The LLRs are generated via successive computations of Euclidean-distance metrics corresponding to candidate noise-recovered words. Noting that the entropy of noise is much smaller than that of information bits, a small number of noise effect guesses generally suffices to hit a code-word, which allows generating LLRs for critical bits; LLR saturation is applied to the remaining bits. In an iterative (turbo) mode, the generated LLRs at a given soft-input, soft-output GRAND iteration serve as enhanced a priori information that adapts noise-sequence guess ordering in a subsequent iteration. Simulations demonstrate that a few turbo-GRAND iterations match the performance of ML-detection-based soft-GRAND in both AWGN and Rayleigh fading channels at a complexity cost that, on average, grows linearly (instead of exponentially) with the number of symbols., Comment: To appear in the IEEE GLOBECOM 2022 proceedings

Published

2022

18. On the Role of Quantization of Soft Information in GRAND

Author

Yuan, Peihong, Duffy, Ken R., Gabhart, Evan P., and Médard, Muriel

Subjects

Computer Science - Information Theory

Abstract

In this work, we investigate guessing random additive noise decoding (GRAND) with quantized soft input. First, we analyze the achievable rate of ordered reliability bits GRAND (ORBGRAND), which uses the rank order of the reliability as quantized soft information. We show that multi-line ORBGRAND can approach capacity for any signal-to-noise ratio (SNR). We then introduce discretized soft GRAND (DSGRAND), which uses information from a conventional quantizer. Simulation results show that DSGRAND well approximates maximum-likelihood (ML) decoding with a number of quantization bits that is in line with current soft decoding implementations. For a (128,106) CRC-concatenated polar code, the basic ORBGRAND is able to match or outperform CRC-aided successive cancellation list (CA-SCL) decoding with codeword list size of 64 and 3 bits of quantized soft information, while DSGRAND outperforms CA-SCL decoding with a list size of 128 codewords. Both ORBGRAND and DSGRAND exhibit approximately an order of magnitude less average complexity and two orders of magnitude smaller memory requirements than CA-SCL.

Published

2022

19. AES as Error Correction: Cryptosystems for Reliable Communication

Author

Cohen, Alejandro, D'Oliveira, Rafael G. L., Duffy, Ken R., Woo, Jongchan, and Médard, Muriel

Subjects

Computer Science - Information Theory, Computer Science - Cryptography and Security

Abstract

In this paper, we show that the Advanced Encryption Standard (AES) cryptosystem can be used as an error-correcting code to obtain reliability over noisy communication and data systems. Moreover, we characterize a family of computational cryptosystems that can potentially be used as well performing error correcting codes. In particular, we show that simple padding followed by a cryptosystem with uniform or pseudo-uniform outputs can approach the error-correcting performance of random codes. We empirically contrast the performance of the proposed approach using AES as error correction with that of Random Linear Codes and CA-Polar codes and show that in practical scenarios, they achieve almost the same performance. Finally, we present a modified counter mode of operation, named input plaintext counter mode, in order to utilize AES for multiple blocks while retaining its error correcting capabilities.

Published

2022

20. Ordered Reliability Bits Guessing Random Additive Noise Decoding

Author

Duffy, Ken R., An, Wei, and Medard, Muriel

Subjects

Computer Science - Information Theory, 94A15, 68P30

Abstract

Error correction techniques traditionally focus on the co-design of restricted code-structures in tandem with code-specific decoders that are computationally efficient when decoding long codes in hardware. Modern applications are, however, driving demand for ultra-reliable low-latency communications (URLLC), rekindling interest in the performance of shorter, higher-rate error correcting codes, and raising the possibility of revisiting universal, code-agnostic decoders. To that end, here we introduce a soft-detection variant of Guessing Random Additive Noise Decoding (GRAND) called Ordered Reliability Bits GRAND that can accurately decode any moderate redundancy block-code. It is designed with efficient circuit implementation in mind, and determines accurate decodings while retaining the original hard detection GRAND algorithm's suitability for a highly parallelized implementation in hardware. ORBGRAND is shown to provide excellent soft decision block error performance for codes of distinct classes (BCH, CA-Polar and RLC) with modest complexity, while providing better block error rate performance than CA-SCL, a state of the art soft detection CA-Polar decoder. ORBGRAND offers the possibility of an accurate, energy efficient soft detection decoder suitable for delivering URLLC in a single hardware realization.

Published

2022

21. Partial Encryption after Encoding for Security and Reliability in Data Systems

Author

Cohen, Alejandro, D'Oliveira, Rafael G. L., Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Information Theory, Computer Science - Cryptography and Security

Abstract

We consider the problem of secure and reliable communication over a noisy multipath network. Previous work considering a noiseless version of our problem proposed a hybrid universal network coding cryptosystem (HUNCC). By combining an information-theoretically secure encoder together with partial encryption, HUNCC is able to obtain security guarantees, even in the presence of an all-observing eavesdropper. In this paper, we propose a version of HUNCC for noisy channels (N-HUNCC). This modification requires four main novelties. First, we present a network coding construction which is jointly, individually secure and error-correcting. Second, we introduce a new security definition which is a computational analogue of individual security, which we call individual indistinguishability under chosen ciphertext attack (individual IND-CCA1), and show that NHUNCC satisfies it. Third, we present a noise based decoder for N-HUNCC, which permits the decoding of the encoded-thenencrypted data. Finally, we discuss how to select parameters for N-HUNCC and its error-correcting capabilities.

Published

2022

22. Syfer: Neural Obfuscation for Private Data Release

Author

Yala, Adam, Quach, Victor, Esfahanizadeh, Homa, D'Oliveira, Rafael G. L., Duffy, Ken R., Médard, Muriel, Jaakkola, Tommi S., and Barzilay, Regina

Subjects

Computer Science - Machine Learning, Computer Science - Cryptography and Security, Computer Science - Computer Vision and Pattern Recognition

Abstract

Balancing privacy and predictive utility remains a central challenge for machine learning in healthcare. In this paper, we develop Syfer, a neural obfuscation method to protect against re-identification attacks. Syfer composes trained layers with random neural networks to encode the original data (e.g. X-rays) while maintaining the ability to predict diagnoses from the encoded data. The randomness in the encoder acts as the private key for the data owner. We quantify privacy as the number of attacker guesses required to re-identify a single image (guesswork). We propose a contrastive learning algorithm to estimate guesswork. We show empirically that differentially private methods, such as DP-Image, obtain privacy at a significant loss of utility. In contrast, Syfer achieves strong privacy while preserving utility. For example, X-ray classifiers built with DP-image, Syfer, and original data achieve average AUCs of 0.53, 0.78, and 0.86, respectively.

Published

2022

23. NeuraCrypt: Hiding Private Health Data via Random Neural Networks for Public Training

Author

Yala, Adam, Esfahanizadeh, Homa, Oliveira, Rafael G. L. D', Duffy, Ken R., Ghobadi, Manya, Jaakkola, Tommi S., Vaikuntanathan, Vinod, Barzilay, Regina, and Medard, Muriel

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence

Abstract

Balancing the needs of data privacy and predictive utility is a central challenge for machine learning in healthcare. In particular, privacy concerns have led to a dearth of public datasets, complicated the construction of multi-hospital cohorts and limited the utilization of external machine learning resources. To remedy this, new methods are required to enable data owners, such as hospitals, to share their datasets publicly, while preserving both patient privacy and modeling utility. We propose NeuraCrypt, a private encoding scheme based on random deep neural networks. NeuraCrypt encodes raw patient data using a randomly constructed neural network known only to the data-owner, and publishes both the encoded data and associated labels publicly. From a theoretical perspective, we demonstrate that sampling from a sufficiently rich family of encoding functions offers a well-defined and meaningful notion of privacy against a computationally unbounded adversary with full knowledge of the underlying data-distribution. We propose to approximate this family of encoding functions through random deep neural networks. Empirically, we demonstrate the robustness of our encoding to a suite of adversarial attacks and show that NeuraCrypt achieves competitive accuracy to non-private baselines on a variety of x-ray tasks. Moreover, we demonstrate that multiple hospitals, using independent private encoders, can collaborate to train improved x-ray models. Finally, we release a challenge dataset to encourage the development of new attacks on NeuraCrypt.

Published

2021

24. Single-cell investigative genetics: Single-cell data produces genotype distributions concentrated at the true genotype across all mixture complexities

Author

Grgicak, Catherine M., Bhembe, Qhawe, Slooten, Klaas, Sheth, Nidhi C., Duffy, Ken R., and Lun, Desmond S.

Published

2024

25. CRC Codes as Error Correction Codes

Author

An, Wei, Médard, Muriel, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

CRC codes have long since been adopted in a vast range of applications. The established notion that they are suitable primarily for error detection can be set aside through use of the recently proposed Guessing Random Additive Noise Decoding (GRAND). Hard-detection (GRAND-SOS) and soft-detection (ORBGRAND) variants can decode any short, high-rate block code, making them suitable for error correction of CRC-coded data. When decoded with GRAND, short CRC codes have error correction capability that is at least as good as popular codes such as BCH codes, but with no restriction on either code length or rate. The state-of-the-art CA-Polar codes are concatenated CRC and Polar codes. For error correction, we find that the CRC is a better short code than either Polar or CA-Polar codes. Moreover, the standard CA-SCL decoder only uses the CRC for error detection and therefore suffers severe performance degradation in short, high rate settings when compared with the performance GRAND provides, which uses all of the CA-Polar bits for error correction. Using GRAND, existing systems can be upgraded from error detection to low-latency error correction without re-engineering the encoder, and additional applications of CRCs can be found in IoT, Ultra-Reliable Low Latency Communication (URLLC), and beyond. The universality of GRAND, its ready parallelized implementation in hardware, and the good performance of CRC as codes make their combination a viable solution for low-latency applications., Comment: This work has been submitted to the IEEE for possible publication

Published

2021

26. Keep the bursts and ditch the interleavers

Author

An, Wei, Médard, Muriel, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

To facilitate applications in IoT, 5G, and beyond, there is an engineering need to enable high-rate, low-latency communications. Errors in physical channels typically arrive in clumps, but most decoders are designed assuming that channels are memoryless. As a result, communication networks rely on interleaving over tens of thousands of bits so that channel conditions match decoder assumptions. Even for short high rate codes, awaiting sufficient data to interleave at the sender and de-interleave at the receiver is a significant source of unwanted latency. Using existing decoders with non-interleaved channels causes a degradation in block error rate performance owing to mismatch between the decoder's channel model and true channel behaviour. Through further development of the recently proposed Guessing Random Additive Noise Decoding (GRAND) algorithm, which we call GRAND-MO for GRAND Markov Order, here we establish that by abandoning interleaving and embracing bursty noise, low-latency, short-code, high-rate communication is possible with block error rates that outperform their interleaved counterparts by a substantial margin. Moreover, while most decoders are twinned to a specific code-book structure, GRAND-MO can decode any code. Using this property, we establish that certain well-known structured codes are ill-suited for use in bursty channels, but Random Linear Codes (RLCs) are robust to correlated noise. This work suggests that the use of RLCs with GRAND-MO is a good candidate for applications requiring high throughput with low latency., Comment: 6 pages

Published

2020

27. Noise Recycling

Author

Cohen, Alejandro, Solomon, Amit, Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Information Theory

Abstract

We introduce Noise Recycling, a method that enhances decoding performance of channels subject to correlated noise without joint decoding. The method can be used with any combination of codes, code-rates and decoding techniques. In the approach, a continuous realization of noise is estimated from a lead channel by subtracting its decoded output from its received signal. This estimate is then used to improve the accuracy of decoding of an orthogonal channel that is experiencing correlated noise. In this design, channels aid each other only through the provision of noise estimates post-decoding. In a Gauss-Markov model of correlated noise, we constructive establish that noise recycling employing a simple successive order enables higher rates than not recycling noise. Simulations illustrate noise recycling can be employed with any code and decoder, and that noise recycling shows Block Error Rate (BLER) benefits when applying the same predetermined order as used to enhance the rate region. Finally, for short codes we establish that an additional BLER improvement is possible through noise recycling with racing, where the lead channel is not pre-determined, but is chosen on the fly based on which decoder completes first., Comment: Appear in IEEE International Symposium on Information Theory, ISIT 2020, based on arXiv:2006.04897

Published

2020

28. Discrete convolution statistic for hypothesis testing

Author

Prevedello, Giulio and Duffy, Ken R.

Subjects

Mathematics - Statistics Theory, 62G05, 62G10, 62G20, 62P10, 62P20

Abstract

The question of testing for equality in distribution between two linear models, each consisting of sums of distinct discrete independent random variables with unequal numbers of observations, has emerged from the biological research. In this case, the computation of classical $\chi^2$ statistics, which would not include all observations, results in loss of power, especially when sample sizes are small. Here, as an alternative that uses all data, the nonparametric maximum likelihood estimator for the distribution of sum of discrete and independent random variables, which we call the convolution statistic, is proposed and its limiting normal covariance matrix determined. To challenge null hypotheses about the distribution of this sum, the generalized Wald's method is applied to define a testing statistic whose distribution is asymptotic to a $\chi^2$ with as many degrees of freedom as the rank of such covariance matrix. Rank analysis also reveals a connection with the roots of the probability generating functions associated to the addend variables of the linear models. A simulation study is performed to compare the convolution test with Pearson's $\chi^2$, and to provide usage guidelines.

Published

2020

29. Soft Maximum Likelihood Decoding using GRAND

Author

Solomon, Amit, Duffy, Ken R., and Médard, Muriel

Subjects

Computer Science - Information Theory

Abstract

Maximum Likelihood (ML) decoding of forward error correction codes is known to be optimally accurate, but is not used in practice as it proves too challenging to efficiently implement. Here we introduce a ML decoder called SGRAND, which is a development of a previously described hard detection ML decoder called GRAND, that fully avails of soft detection information and is suitable for use with any arbitrary high-rate, short-length block code. We assess SGRAND's performance on CRC-aided Polar (CA-Polar) codes, which will be used for all control channel communication in 5G NR, comparing its accuracy with CRC-Aided Successive Cancellation List decoding (CA-SCL), a state-of-the-art soft-information decoder specific to CA-Polar codes.

Published

2020

30. Ordered Reliability Bits Guessing Random Additive Noise Decoding

Author

Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

Modern applications are driving demand for ultra-reliable low-latency communications, rekindling interest in the performance of short, high-rate error correcting codes. To that end, here we introduce a soft-detection variant of Guessing Random Additive Noise Decoding (GRAND) called Ordered Reliability Bits GRAND that can decode any short, high-rate block-code. For a code of $n$ bits, it avails of no more than $\lceil\log_2(n)\rceil$ bits of code-book-independent quantized soft detection information per received bit to determine an accurate decoding while retaining the original algorithm's suitability for a highly parallelized implementation in hardware. ORBGRAND is shown to provide similar block error performance for codes of distinct classes (BCH, CA-Polar and RLC) with low complexity, while providing better block error rate performance than CA-SCL, a state of the art soft detection CA-Polar decoder.

Published

2020

31. Inferring differentiation order in adaptive immune responses from population level data

Author

Miles, Alexander S., Hodgkin, Philip D., and Duffy, Ken R.

Subjects

Quantitative Biology - Cell Behavior, Quantitative Biology - Populations and Evolution

Abstract

A hallmark of the adaptive immune response is the proliferation of pathogen-specific lymphocytes that leave in their wake a long lived population of cells that provide lasting immunity. A subject of ongoing investigation is when during an adaptive immune response those memory cells are produced. In two ground-breaking studies, Buchholz et al. (Science, 2013) and Gerlach et al. (Science, 2013) employed experimental methods that allowed identification of offspring from individual lymphocytes in vivo, which we call clonal data, at a single time point. Through the development, application and fitting of a mathematical model, Buchholz et al. (Science, 2013) concluded that, if memory is produced during the expansion phase, memory cell precursors are made before the effector cells that clear the original pathogen. We sought to determine the general validity and power of the modeling approach introduced in Buchholz et al. (Science, 2013) for quickly evaluating differentiation networks by adapting it to make it suitable for drawing inferences from more readily available non-clonal phenotypic proportion time-courses. We first established the method drew consistent deductions when fit to the non-clonal data in Buchholz et al. (Science, 2013) itself. We fit a variant of the model to data reported in Badovinac et al. (J. Immun., 2007), Schlub et al. (Immun. & Cell Bio., 2010), and Kinjo et al. (Nature Commun., 2015) with necessary simplifications to match different reported data in these papers. The deduction from the model was consistent with that in Buchholz et al. (Science, 2013), albeit with questionable parameterizations. An alternative possibility, supported by the data in Kinjo et al. (Nature Commun., 2015), is that memory precursors are created after the expansion phase, which is a deduction not possible from the mathematical methods provided in Buchholz et al. (Science, 2013).

Published

2019

32. Guessing random additive noise decoding with symbol reliability information (SRGRAND)

Author

Duffy, Ken R., Médard, Muriel, and An, Wei

Subjects

Computer Science - Information Theory, E.4

Abstract

The design and implementation of error correcting codes has long been informed by two fundamental results: Shannon's 1948 capacity theorem, which established that long codes use noisy channels most efficiently; and Berlekamp, McEliece, and Van Tilborg's 1978 theorem on the NP-hardness of decoding linear codes. These results shifted focus away from creating code-independent decoders, but recent low-latency communication applications necessitate relatively short codes, providing motivation to reconsider the development of universal decoders. We introduce a scheme for employing binarized symbol soft information within Guessing Random Additive Noise Decoding, a universal hard detection decoder. We incorporate codebook-independent quantization of soft information to indicate demodulated symbols to be reliable or unreliable. We introduce two decoding algorithms: one identifies a conditional Maximum Likelihood (ML) decoding; the other either reports a conditional ML decoding or an error. For random codebooks, we present error exponents and asymptotic complexity, and show benefits over hard detection. As empirical illustrations, we compare performance with majority logic decoding of Reed-Muller codes, with Berlekamp-Massey decoding of Bose-Chaudhuri-Hocquenghem codes, with CA-SCL decoding of CA-Polar codes, and establish the performance of Random Linear Codes, which require a universal decoder and offer a broader palette of code sizes and rates than traditional codes., Comment: This work has been submitted to the IEEE for possible publication

Published

2019

33. The variance of the average depth of a pure birth process converges to 7

Author

Duffy, Ken R., Meli, Gianfelice, and Shneer, Seva

Subjects

Mathematics - Probability, 60J80

Abstract

If trees are constructed from a pure birth process and one defines the depth of a leaf to be the number of edges to its root, it is known that the variance in the depth of a randomly selected leaf of a randomly selected tree grows linearly in time. In this letter, we instead consider the variance of the average depth of leaves within each individual tree, establishing that, in contrast, it converges to a constant, $7$. This result indicates that while the variance in leaf depths amongst the ensemble of pure birth processes undergoes large fluctuations, the average depth across individual trees is much more consistent.

Published

2018

34. Evidentiary evaluation of single cells renders highly informative forensic comparisons across multifarious admixtures

Author

Duffy, Ken R., Lun, Desmond S., Mulcahy, Madison M., O’Donnell, Leah, Sheth, Nidhi, and Grgicak, Catherine M.

Published

2023

35. Sample Path Properties of the Average Generation of a Bellman-Harris Process

Author

Meli, Gianfelice, Weber, Tom S., and Duffy, Ken R.

Subjects

Mathematics - Probability, Quantitative Biology - Quantitative Methods, 92D25, 60J85

Abstract

Motivated by a recently proposed design for a DNA coded randomised algorithm that enables inference of the average generation of a collection of cells descendent from a common progenitor, here we establish strong convergence properties for the average generation of a super-critical Bellman-Harris process. We further extend those results to a two-type Bellman-Harris process where one type can give rise to the other, but not vice versa. These results further affirm the estimation method's potential utility by establishing its long run accuracy on individual sample-paths, and significantly expanding its remit to encompass cellular development that gives rise to differentiated offspring with distinct population dynamics.

Published

2018

36. Capacity-achieving Guessing Random Additive Noise Decoding (GRAND)

Author

Duffy, Ken R., Li, Jiange, and Médard, Muriel

Subjects

Computer Science - Information Theory, 94A24, E.4

Abstract

We introduce a new algorithm for realizing Maximum Likelihood (ML) decoding in discrete channels with or without memory. In it, the receiver rank orders noise sequences from most likely to least likely. Subtracting noise from the received signal in that order, the first instance that results in a member of the code-book is the ML decoding. We name this algorithm GRAND for Guessing Random Additive Noise Decoding. We establish that GRAND is capacity-achieving when used with random code-books. For rates below capacity we identify error exponents, and for rates beyond capacity we identify success exponents. We determine the scheme's complexity in terms of the number of computations the receiver performs. For rates beyond capacity, this reveals thresholds for the number of guesses by which if a member of the code-book is identified it is likely to be the transmitted code-word. We introduce an approximate ML decoding scheme where the receiver abandons the search after a fixed number of queries, an approach we dub GRANDAB, for GRAND with ABandonment. While not an ML decoder, we establish that the algorithm GRANDAB is also capacity-achieving for an appropriate choice of abandonment threshold, and characterize its complexity, error and success exponents. Worked examples are presented for Markovian noise that indicate these decoding schemes substantially out-perform the brute force decoding approach., Comment: IEEE Transactions on Information Theory, to appear

Published

2018

37. Replicative history marks transcriptional and functional disparity in the CD8+ T cell memory pool

Author

Bresser, Kaspar, Kok, Lianne, Swain, Arpit C., King, Lisa A., Jacobs, Laura, Weber, Tom S., Perié, Leïla, Duffy, Ken R., de Boer, Rob J., Scheeren, Ferenc A., and Schumacher, Ton N.

Published

2022

38. Privacy with Estimation Guarantees

Author

Wang, Hao, Vo, Lisa, Calmon, Flavio P., Médard, Muriel, Duffy, Ken R., and Varia, Mayank

Subjects

Computer Science - Information Theory, Computer Science - Machine Learning

Abstract

We study the central problem in data privacy: how to share data with an analyst while providing both privacy and utility guarantees to the user that owns the data. In this setting, we present an estimation-theoretic analysis of the privacy-utility trade-off (PUT). Here, an analyst is allowed to reconstruct (in a mean-squared error sense) certain functions of the data (utility), while other private functions should not be reconstructed with distortion below a certain threshold (privacy). We demonstrate how chi-square information captures the fundamental PUT in this case and provide bounds for the best PUT. We propose a convex program to compute privacy-assuring mappings when the functions to be disclosed and hidden are known a priori and the data distribution is known. We derive lower bounds on the minimum mean-squared error of estimating a target function from the disclosed data and evaluate the robustness of our approach when an empirical distribution is used to compute the privacy-assuring mappings instead of the true data distribution. We illustrate the proposed approach through two numerical experiments.

Published

2017

39. Principal Inertia Components and Applications

Author

Calmon, Flavio P., Makhdoumi, Ali, Médard, Muriel, Varia, Mayank, Christiansen, Mark, and Duffy, Ken R.

Subjects

Computer Science - Information Theory

Abstract

We explore properties and applications of the Principal Inertia Components (PICs) between two discrete random variables $X$ and $Y$. The PICs lie in the intersection of information and estimation theory, and provide a fine-grained decomposition of the dependence between $X$ and $Y$. Moreover, the PICs describe which functions of $X$ can or cannot be reliably inferred (in terms of MMSE) given an observation of $Y$. We demonstrate that the PICs play an important role in information theory, and they can be used to characterize information-theoretic limits of certain estimation problems. In privacy settings, we prove that the PICs are related to fundamental limits of perfect privacy., Comment: Overlaps with arXiv:1405.1472 and arXiv:1310.1512

Published

2017

40. Inferring Differentiation Order in Adaptive Immune Responses from Population-Level Data

Author

Miles, Alexander S., Hodgkin, Philip D., Duffy, Ken R., Molina-París, Carmen, editor, and Lythe, Grant, editor

Published

2021

41. The a posteriori probability of the number of contributors when conditioned on an assumed contributor

Author

Grgicak, Catherine M., Duffy, Ken R., and Lun, Desmond S.

Published

2021

42. Site-specific recombinatorics: in situ cellular barcoding with the Cre Lox system

Author

Weber, Tom S., Dukes, Mark, Miles, Denise, Glaser, Stefan, Naik, Shalin, and Duffy, Ken R.

Subjects

Quantitative Biology - Cell Behavior, Quantitative Biology - Quantitative Methods

Abstract

Cellular barcoding is a significant, recently developed, biotechnology tool that enables the familial identification of progeny of individual cells in vivo. Most existing approaches rely on ex vivo viral transduction of cells with barcodes, followed by adoptive transfer into an animal, which works well for some systems, but precludes barcoding cells in their native environment, such as those inside solid tissues. With a view to overcoming this limitation, we propose a new design for a genetic barcoding construct based on the Cre Lox system that induces randomly created stable barcodes in cells in situ by exploiting inherent sequence distance constraints during site-specific recombination. Leveraging this previously unused feature, we identify the cassette with maximal code diversity. This proves to be orders of magnitude higher than what is attainable with previously considered Cre Lox barcoding approaches and is well suited for its intended applications as it exceeds the number of lymphocytes or hematopoietic progenitor cells in mice. Moreover, it can be built using established technology.

Published

2016

43. Estimating large deviation rate functions

Author

Duffy, Ken R. and Williamson, Brendan D.

Subjects

Mathematics - Probability

Abstract

Establishing a Large Deviation Principle (LDP) proves to be a powerful result for a vast number of stochastic models in many application areas of probability theory. The key object of an LDP is the large deviations rate function, from which probabilistic estimates of rare events can be determined. In order make these results empirically applicable, it would be necessary to estimate the rate function from observations. This is the question we address in this article for the best known and most widely used LDP: Cram\'er's theorem for random walks. We establish that even when only a narrow LDP holds for Cram\'er's Theorem, as occurs for heavy-tailed increments, one gets a LDP for estimating the random walk's rate function in the space of convex lower-semicontinuous functions equipped with the Attouch-Wets topology via empirical estimates of the moment generating function. This result may seem surprising as it is saying that for Cram\'er's theorem, one can quickly form non-parametric estimates of the function that governs the likelihood of rare events.

Published

2015

44. Inferring average generation via division-linked labeling

Author

Weber, Tom S., Perie, Leila, and Duffy, Ken R.

Subjects

Quantitative Biology - Quantitative Methods, Mathematics - Probability, 92D25, 60J85

Abstract

For proliferating cells subject to both division and death, how can one estimate the average generation number of the living population without continuous observation or a division-diluting dye? In this paper we provide a method for cell systems such that at each division there is an unlikely, heritable one-way label change that has no impact other than to serve as a distinguishing marker. If the probability of label change per cell generation can be determined and the proportion of labeled cells at a given time point can be measured, we establish that the average generation number of living cells can be estimated. Crucially, the estimator does not depend on knowledge of the statistics of cell cycle, death rates or total cell numbers. We validate the estimator and illustrate its features through comparison with published data and physiologically parameterized stochastic simulations, using it to suggest new experimental designs.

Published

2015

45. Hiding Symbols and Functions: New Metrics and Constructions for Information-Theoretic Security

Author

Calmon, Flavio du Pin, Médard, Muriel, Varia, Mayank, Duffy, Ken R., Christiansen, Mark M., and Zeger, Linda M.

Subjects

Computer Science - Information Theory

Abstract

We present information-theoretic definitions and results for analyzing symmetric-key encryption schemes beyond the perfect secrecy regime, i.e. when perfect secrecy is not attained. We adopt two lines of analysis, one based on lossless source coding, and another akin to rate-distortion theory. We start by presenting a new information-theoretic metric for security, called symbol secrecy, and derive associated fundamental bounds. We then introduce list-source codes (LSCs), which are a general framework for mapping a key length (entropy) to a list size that an eavesdropper has to resolve in order to recover a secret message. We provide explicit constructions of LSCs, and demonstrate that, when the source is uniformly distributed, the highest level of symbol secrecy for a fixed key length can be achieved through a construction based on minimum-distance separable (MDS) codes. Using an analysis related to rate-distortion theory, we then show how symbol secrecy can be used to determine the probability that an eavesdropper correctly reconstructs functions of the original plaintext. We illustrate how these bounds can be applied to characterize security properties of symmetric-key encryption schemes, and, in particular, extend security claims based on symbol secrecy to a functional setting., Comment: Submitted to IEEE Transactions on Information Theory

Published

2015

46. Towards developing forensically relevant single-cell pipelines by incorporating direct-to-PCR extraction: compatibility, signal quality, and allele detection

Author

Sheth, Nidhi, Swaminathan, Harish, Gonzalez, Amanda J., Duffy, Ken R., and Grgicak, Catherine M.

Published

2021

47. A large-scale validation of NOCIt’s a posteriori probability of the number of contributors and its integration into forensic interpretation pipelines

Author

Grgicak, Catherine M., Karkar, Slim, Yearwood-Garcia, Xia, Alfonse, Lauren E., Duffy, Ken R., and Lun, Desmond S.

Published

2020

48. Single-cell investigative genetics: Single-cell data produces genotype distributions concentrated at the true genotype across all mixture complexities

Author

Grgicak, Catherine M., primary, Bhembe, Qhawe, additional, Slooten, Klaas, additional, Sheth, Nidhi C., additional, Duffy, Ken R., additional, and Lun, Desmond S., additional

Published

2023

49. Multi-user guesswork and brute force security

Author

Christiansen, Mark M., Duffy, Ken R., Calmon, Flavio du Pin, and Medard, Muriel

Subjects

Computer Science - Information Theory

Abstract

The Guesswork problem was originally motivated by a desire to quantify computational security for single user systems. Leveraging recent results from its analysis, we extend the remit and utility of the framework to the quantification of the computational security for multi-user systems. In particular, assume that $V$ users independently select strings stochastically from a finite, but potentially large, list. An inquisitor who does not know which strings have been selected wishes to identify $U$ of them. The inquisitor knows the selection probabilities of each user and is equipped with a method that enables the testing of each (user, string) pair, one at a time, for whether that string had been selected by that user. Here we establish that, unless $U=V$, there is no general strategy that minimizes the distribution of the number of guesses, but in the asymptote as the strings become long we prove the following: by construction, there is an asymptotically optimal class of strategies; the number of guesses required in an asymptotically optimal strategy satisfies a large deviation principle with a rate function, which is not necessarily convex, that can be determined from the rate functions of optimally guessing individual users' strings; if all user's selection statistics are identical, the exponential growth rate of the average guesswork as the string-length increases is determined by the specific R\'enyi entropy of the string-source with parameter $(V-U+1)/(V-U+2)$, generalizing the known $V=U=1$ case; and that the Shannon entropy of the source is a lower bound on the average guesswork growth rate for all $U$ and $V$, thus providing a bound on computational security for multi-user systems. Examples are presented to illustrate these results and their ramifications for systems design.

Published

2014

50. Manipulating niche composition limits damage to haematopoietic stem cells during Plasmodium infection

Author

Haltalli, Myriam L. R., Watcham, Samuel, Wilson, Nicola K., Eilers, Kira, Lipien, Alexander, Ang, Heather, Birch, Flora, Anton, Sara Gonzalez, Pirillo, Chiara, Ruivo, Nicola, Vainieri, Maria L., Pospori, Constandina, Sinden, Robert E., Luis, Tiago C., Langhorne, Jean, Duffy, Ken R., Göttgens, Berthold, Blagborough, Andrew M., and Lo Celso, Cristina

Published

2020