On Adaptivity Gaps of Influence Maximization under the Independent Cascade Model with Full Adoption Feedback

Binghui Peng; Wei Chen

arxiv: 1907.01707 · v1 · pith:RUTPWHV4new · submitted 2019-07-03 · 💻 cs.SI

On Adaptivity Gaps of Influence Maximization under the Independent Cascade Model with Full Adoption Feedback

Wei Chen , Binghui Peng This is my paper

Pith reviewed 2026-05-25 10:07 UTC · model grok-4.3

classification 💻 cs.SI

keywords influence maximizationadaptivity gapindependent cascade modelfull adoption feedbackarborescencesbipartite graphsstochastic optimization

0 comments

The pith

The adaptivity gap of influence maximization with full adoption feedback is at most 2e/(e-1) on in-arborescences and 2 on out-arborescences.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

This paper establishes upper bounds on the adaptivity gap for influence maximization under the independent cascade model when full adoption feedback is available after each seed choice. It focuses on restricted graph families including in-arborescences, out-arborescences, and bipartite graphs, proving that the gap lies between e/(e-1) and 2e/(e-1) for in-arborescences and between e/(e-1) and 2 for out-arborescences. These are presented as the first constant upper bounds in the full-adoption feedback model. Sympathetic readers care because the results quantify the additional value of adaptive strategies over non-adaptive ones in network diffusion, informing whether adaptivity is worth the implementation cost in stochastic settings.

Core claim

We prove that the adaptivity gap for the in-arborescence is between [e/(e-1), 2e/(e-1)] and for the out-arborescence, the gap is between [e/(e-1), 2]. These are the first constant upper bounds in the full-adoption feedback model. We provide several novel ideas to tackle with correlated feedback appearing in the adaptive stochastic optimization, which we believe to be of independent interests. Similar constant bounds are derived for bipartite graphs.

What carries the argument

The adaptivity gap, the worst-case ratio of the expected spread achieved by an optimal adaptive policy to that of an optimal non-adaptive policy under the independent cascade model with full adoption feedback.

If this is right

Adaptive policies improve expected influence by at most a factor of 2e/(e-1) over non-adaptive policies on in-arborescences.
The improvement factor is at most 2 on out-arborescences.
Constant-factor bounds also hold on bipartite graphs.
Novel techniques handle correlated feedback arising in adaptive stochastic optimization.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The constant gaps imply that non-adaptive seeding strategies achieve near-optimal performance on these tree-structured graphs, reducing the need for complex adaptive algorithms in such cases.
The methods for managing correlated feedback may extend to other adaptive decision problems with partial observations beyond influence maximization.
Similar gap analysis could be attempted on additional restricted graph families like planar graphs or low-treewidth networks to test broader applicability.
pith_inferences

Load-bearing premise

The analysis assumes the underlying graphs belong to restricted families such as in-arborescences, out-arborescences, and bipartite graphs, with diffusion following the independent cascade model and full adoption feedback available after each seed choice.

What would settle it

An explicit in-arborescence instance where the adaptivity gap exceeds 2e/(e-1) under the independent cascade model with full adoption feedback would falsify the claimed upper bound.

read the original abstract

In this paper, we study the adaptivity gap of the influence maximization problem under independent cascade model when full-adoption feedback is available. Our main results are to derive upper bounds on several families of well-studied influence graphs, including in-arborescences, out-arborescences and bipartite graphs. Especially, we prove that the adaptivity gap for the in-arborescence is between $[\frac{e}{e-1}, \frac{2e}{e - 1}]$ and for the out-arborescence, the gap is between $[\frac{e}{e-1}, 2]$. These are the first constant upper bounds in the full-adoption feedback model. We provide several novel ideas to tackle with correlated feedback appearing in the adaptive stochastic optimization, which we believe to be of independent interests.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper gives the first constant upper bounds on adaptivity gaps for in- and out-arborescences under IC with full-adoption feedback.

read the letter

The central result is that the adaptivity gap sits between e/(e-1) and 2e/(e-1) for in-arborescences and between e/(e-1) and 2 for out-arborescences. These are the first constant upper bounds shown in the full-adoption feedback model, which is the main advance over earlier work that only had lower bounds or no constants at all for this setting. The authors also extend the analysis to bipartite graphs. They introduce some new ways to handle the correlations that appear when feedback from one seed affects later choices, and those techniques look like they could be reused elsewhere. The proofs exploit the acyclic structure of arborescences, which makes the analysis tractable where general graphs remain open. The limitation is exactly what the abstract states: everything is restricted to these narrow graph families. No general-graph result is claimed, and the bounds are not shown to be tight. The paper does not include experiments or code, so the claims rest entirely on the derivations. For readers working on adaptive influence maximization or stochastic submodular optimization, the constants and the feedback-handling ideas are worth seeing. It is a focused theoretical note rather than a broad contribution, but the gap it closes is real and the argument appears internally consistent. A serious editor should send it to referees.

Referee Report

0 major / 2 minor

Summary. The paper studies the adaptivity gap (adaptive OPT over non-adaptive OPT) of influence maximization under the independent cascade model with full-adoption feedback. It derives the first constant upper bounds on this gap for restricted graph families: for in-arborescences the gap lies in [e/(e-1), 2e/(e-1)], and for out-arborescences in [e/(e-1), 2]; analogous results are given for bipartite graphs. Novel techniques are introduced to handle correlated feedback arising from the adaptive setting.

Significance. If the stated proofs are correct, the work supplies the first constant-factor upper bounds on the adaptivity gap under full-adoption feedback for these natural graph classes, together with explicit lower-bound constructions. The techniques developed for correlated feedback are likely to be reusable in other adaptive stochastic combinatorial optimization settings.

minor comments (2)

[§1] §1: the definition of the adaptivity gap should explicitly reference the full-adoption feedback model in the notation to avoid ambiguity with the no-feedback case.
[Proof of Theorem 3.2] The proof sketches for the upper bounds on out-arborescences could benefit from an explicit statement of the induction hypothesis used to bound the value of the adaptive policy.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for the positive review, the recognition of the novelty of our constant upper bounds on adaptivity gaps under full-adoption feedback, and the recommendation to accept. We are glad that the reusable techniques for handling correlated feedback are viewed as potentially of independent interest.

Circularity Check

0 steps flagged

No significant circularity; self-contained theoretical proofs

full rationale

The paper establishes constant upper bounds on adaptivity gaps via direct mathematical analysis of correlated feedback under the independent cascade model, restricted to in-arborescences, out-arborescences, and bipartite graphs. These derivations rely on novel handling of adaptive stochastic optimization properties specific to the graph families and feedback model, without any reduction of claimed results to fitted parameters, self-definitions, or load-bearing self-citations. The bounds are derived as independent first-principles results on the defined quantities (adaptive OPT / non-adaptive OPT ratios), making the central claims self-contained.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Review is based solely on the abstract; no free parameters, invented entities, or non-standard axioms are identifiable from the given text. Standard assumptions of the independent cascade model are implicit but not detailed.

pith-pipeline@v0.9.0 · 5667 in / 1096 out tokens · 24493 ms · 2026-05-25T10:07:47.981916+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

40 extracted references · 40 canonical work pages · 3 internal anchors

[1]

, Sviridenko, M

Adamczyk, M. , Sviridenko, M. , and W ard, J. 2016. Submodular stochastic probing on matroids. Mathematics of Operations Research 41, 3, 1022–1038

work page 2016
[2]

, Gamzu, I

Alon, N. , Gamzu, I. , and Tennenholtz, M. 2012. Optimizing budget allocation among channels and inﬂuencers. In WWW. ACM, 381–388

work page 2012
[3]

and Nazerzadeh, H

Asadpour, A. and Nazerzadeh, H. 2015. Maximizing stochastic monotone submodular functions. Management Science 62, 8, 2374–2391

work page 2015
[4]

, Papadimitriou, C

Badanidiyuru, A. , Papadimitriou, C. , Rubinstein, A. , Seeman, L. , and Singer, Y

work page
[5]

Locally adaptive optimization: Adaptive seeding for monotone submodular functions. In SODA. SIAM

work page
[6]

, Bonchi, F

Barbieri, N. , Bonchi, F. , and Manco, G. 2012. Topic-aware social inﬂuence propagation models. In ICDM’12

work page 2012
[7]

, Kempe, D

Bharathi, S. , Kempe, D. , and Salek, M. 2007. Competitive inﬂuence maximization in social networks. In WINE. Springer, 306–311

work page 2007
[8]

, Brautbar, M

Borgs, C. , Brautbar, M. , Chayes, J. , and Lucier, B. 2014. Maximizing social inﬂuence in nearly optimal time. In SODA’14. ACM-SIAM, 946–957

work page 2014
[9]

(Near) Optimal Adaptivity Gaps for Stochastic Multi-Value Probing

Bradac, D. , Singla, S. , and Zuzic, G. 2019. (near) optimal adaptivity gaps for stochastic multi-value probing. arXiv preprint arXiv:1902.01461

work page internal anchor Pith review Pith/arXiv arXiv 2019
[10]

, Chekuri, C

Calinescu, G. , Chekuri, C. , P´al, M. , and Vondr ´ak, J. 2011. Maximizing a monotone submodular function subject to a matroid constraint. SIAM Journal on Computing 40, 6, 1740– 1766

work page 2011
[11]

, Vondrak, J

Chekuri, C. , Vondrak, J. , and Zenklusen, R. 2010. Dependent randomized rounding via exchange properties of combinatorial structures. In FOCS. IEEE, 575–584. 11

work page 2010
[12]

, Lakshmanan, L

Chen, W. , Lakshmanan, L. V. , and Castillo, C. 2013. Information and Inﬂuence Prop- agation in Social Networks . Morgan & Claypool Publishers

work page 2013
[13]

, W ang, C., and W ang, Y

Chen, W. , W ang, C., and W ang, Y. 2010. Scalable inﬂuence maximization for prevalent viral marketing in large-scale social networks. In KDD’10

work page 2010
[14]

, W ang, Y., and Yang, S

Chen, W. , W ang, Y., and Yang, S. 2009. Eﬃcient inﬂuence maximization in social net- works. In Proceedings of the 15th ACM SIGKDD . ACM

work page 2009
[15]

and Sakaue, S

Fujii, K. and Sakaue, S. 2019. Beyond adaptive submodularity: Approximation guara ntees of greedy policy with adaptive submodularity ratio. In ICML. 2042–2051

work page 2019
[16]

and Krause, A

Golovin, D. and Krause, A. 2011. Adaptive submodularity:theory and applications in active learning and stochastic optimization. Journal of Artiﬁcial Intelligence Research 42 , 427–

work page 2011
[17]

arXiv version (arxiv.org/abs/1003.3967) includes di scussions on the myopic feedback model

work page internal anchor Pith review Pith/arXiv arXiv
[18]

, Nagarajan, V

Gupta, A. , Nagarajan, V. , and Singla, S. 2016. Algorithms and adaptivity gaps for stochastic probing. In SODA. SIAM

work page 2016
[19]

, Nagarajan, V

Gupta, A. , Nagarajan, V. , and Singla, S. 2017. Adaptivity gaps for stochastic probing: Submodular and XOS functions. In SODA. SIAM

work page 2017
[20]

, and Kawarabayashi, K.-I

Hatano, D., Fukunaga, T. , and Kawarabayashi, K.-I. 2016. Adaptive budget allocation for maximizing inﬂuence of advertisements. In IJCAI. 3600–3608

work page 2016
[21]

, Kleinberg, J

Kempe, D. , Kleinberg, J. , and Tardos, ´E. 2003. Maximizing the spread of inﬂuence through a social network. In Proceedings of the ninth ACM SIGKDD . ACM, 137–146

work page 2003
[22]

, Kleinberg, J

Kempe, D. , Kleinberg, J. M. , and Tardos, ´E. 2015. Maximizing the spread of inﬂuence through a social network. Theory of Computing 11, 4, 105–147. Conference version appeared in KDD’2003

work page 2015
[23]

, Krause, A

Leskovec, J. , Krause, A. , Guestrin, C. , F aloutsos, C., V anbriesen, J. M. , and Glance, N. 2007. Cost-eﬀective outbreak detection in networks. In ACM Knowledge Discovery and Data Mining . 420–429

work page 2007
[24]

, F an, J., W ang, Y., and Tan, K

Li, Y. , F an, J., W ang, Y., and Tan, K. 2018. Inﬂuence maximization on social graphs: A survey. IEEE Trans. Knowl. Data Eng. 30, 10, 1852–1872

work page 2018
[25]

, Chen, W

Lin, Y. , Chen, W. , and Lui, J. C. 2017. Boosting information spread: An algorithmic approach. In ICDE. IEEE, 883–894

work page 2017
[26]

, Chen, W

Lu, W. , Chen, W. , and Lakshmanan, L. V. 2015. From competition to complementarity: comparative inﬂuence diﬀusion and maximization. Proceedings of the VLDB Endowment 9, 2, 60–71

work page 2015
[27]

, Zhang, Z

Lu, Z. , Zhang, Z. , and Wu, W. 2017. Solution of bharathi–kempe–salek conjecture for inﬂuence maximization on arborescence. Journal of Combinatorial Optimization 33, 2, 803–808

work page 2017
[28]

Adaptive Influence Maximization with Myopic Feedback

Peng, B. and Chen, W. 2019. Adaptive inﬂuence maximization with myopic feedback . arXiv preprint arXiv:1905.11663

work page internal anchor Pith review Pith/arXiv arXiv 2019
[29]

, Tziortziotis, N., and V azirgiannis, M

Salha, G. , Tziortziotis, N., and V azirgiannis, M. 2018. Adaptive submodular inﬂuence maximization with myopic feedback. In ASONAM. IEEE, 455–462. 12

work page 2018
[30]

and Singer, Y

Seeman, L. and Singer, Y. 2013. Adaptive seeding in social networks. In FOCS. IEEE, 459–468

work page 2013
[31]

Singer, Y. 2016. Inﬂuence maximization through adaptive seeding. ACM SIGecom Ex- changes 15, 1, 32–59

work page 2016
[32]

, Kakimura, N

Soma, T. , Kakimura, N. , Inaba, K. , and Kawarabayashi, K.-i. 2014. Optimal budget allocation: Theoretical guarantee and eﬃcient algorithm. In ICML

work page 2014
[33]

, Huang, W

Sun, L. , Huang, W. , Yu, P. S. , and Chen, W. 2018. Multi-round inﬂuence maximization. In KDD. ACM, 2249–2258

work page 2018
[34]

, Shi, Y

Tang, Y. , Shi, Y. , and Xiao, X. 2015. Inﬂuence maximization in near-linear time: A martingale approach. In SIGMOD’15. ACM, 1539–1554

work page 2015
[35]

, and Shi, Y

Tang, Y., Xiao, X. , and Shi, Y. 2014. Inﬂuence maximization: near-optimal time complex- ity meets practical eﬃciency. In SIGMOD’14

work page 2014
[36]

Tong, G. , Wu, W. , Tang, S. , and Du, D.-Z. 2017. Adaptive inﬂuence maximization in dynamic social networks. IEEE/ACM Transactions on Networking (TON) 25, 1, 112–125

work page 2017
[37]

Vondr´ak, J. 2007. Submodularity in combinatorial optimization

work page 2007
[38]

, and Cui, L

W ang, A., Wu, W. , and Cui, L. 2016. On bharathi–kempe–salek conjecture for inﬂuence maximization on arborescence. Journal of Combinatorial Optimization 31, 4, 1678–1684

work page 2016
[39]

and Tang, S

Yuan, J. and Tang, S. 2017. No time to observe: Adaptive inﬂuence maximization wi th partial feedback. In IJCAI. 13 Appendix For convenience, we restate the lemmas and theorems in the ap pendix before the proofs. A Missing Proofs from Section 3 Lemma 3.2. E [f (Ψ(1))] = F (1 −e−x1, · · ·, 1 −e−xn) ≤F (x1, · · ·,x n). Proof. Notice that in the Poisson proc...

work page 2017
[40]

Lemma 4.3

( 26) ( 27), we complete the proof. Lemma 4.3. For any i, we have F1(0, · · ·, 0,x i, · · ·,x n) −F1(0, · · ·, 0,x i+1, · · ·,x n) = xipi (1 −Fi(0, · · ·, 0,x i+1, · · ·,x n)). Proof. Since the node 1’s predecessors form a directed line, for any i we have F1(0, · · ·, 0,x i, · · ·,x n) −F1(0, · · ·, 0,x i+1, · · ·,x n) =pi · (Fi(0, · · ·, 0,x i, · · ·,x n...

work page

[1] [1]

, Sviridenko, M

Adamczyk, M. , Sviridenko, M. , and W ard, J. 2016. Submodular stochastic probing on matroids. Mathematics of Operations Research 41, 3, 1022–1038

work page 2016

[2] [2]

, Gamzu, I

Alon, N. , Gamzu, I. , and Tennenholtz, M. 2012. Optimizing budget allocation among channels and inﬂuencers. In WWW. ACM, 381–388

work page 2012

[3] [3]

and Nazerzadeh, H

Asadpour, A. and Nazerzadeh, H. 2015. Maximizing stochastic monotone submodular functions. Management Science 62, 8, 2374–2391

work page 2015

[4] [4]

, Papadimitriou, C

Badanidiyuru, A. , Papadimitriou, C. , Rubinstein, A. , Seeman, L. , and Singer, Y

work page

[5] [5]

Locally adaptive optimization: Adaptive seeding for monotone submodular functions. In SODA. SIAM

work page

[6] [6]

, Bonchi, F

Barbieri, N. , Bonchi, F. , and Manco, G. 2012. Topic-aware social inﬂuence propagation models. In ICDM’12

work page 2012

[7] [7]

, Kempe, D

Bharathi, S. , Kempe, D. , and Salek, M. 2007. Competitive inﬂuence maximization in social networks. In WINE. Springer, 306–311

work page 2007

[8] [8]

, Brautbar, M

Borgs, C. , Brautbar, M. , Chayes, J. , and Lucier, B. 2014. Maximizing social inﬂuence in nearly optimal time. In SODA’14. ACM-SIAM, 946–957

work page 2014

[9] [9]

(Near) Optimal Adaptivity Gaps for Stochastic Multi-Value Probing

Bradac, D. , Singla, S. , and Zuzic, G. 2019. (near) optimal adaptivity gaps for stochastic multi-value probing. arXiv preprint arXiv:1902.01461

work page internal anchor Pith review Pith/arXiv arXiv 2019

[10] [10]

, Chekuri, C

Calinescu, G. , Chekuri, C. , P´al, M. , and Vondr ´ak, J. 2011. Maximizing a monotone submodular function subject to a matroid constraint. SIAM Journal on Computing 40, 6, 1740– 1766

work page 2011

[11] [11]

, Vondrak, J

Chekuri, C. , Vondrak, J. , and Zenklusen, R. 2010. Dependent randomized rounding via exchange properties of combinatorial structures. In FOCS. IEEE, 575–584. 11

work page 2010

[12] [12]

, Lakshmanan, L

Chen, W. , Lakshmanan, L. V. , and Castillo, C. 2013. Information and Inﬂuence Prop- agation in Social Networks . Morgan & Claypool Publishers

work page 2013

[13] [13]

, W ang, C., and W ang, Y

Chen, W. , W ang, C., and W ang, Y. 2010. Scalable inﬂuence maximization for prevalent viral marketing in large-scale social networks. In KDD’10

work page 2010

[14] [14]

, W ang, Y., and Yang, S

Chen, W. , W ang, Y., and Yang, S. 2009. Eﬃcient inﬂuence maximization in social net- works. In Proceedings of the 15th ACM SIGKDD . ACM

work page 2009

[15] [15]

and Sakaue, S

Fujii, K. and Sakaue, S. 2019. Beyond adaptive submodularity: Approximation guara ntees of greedy policy with adaptive submodularity ratio. In ICML. 2042–2051

work page 2019

[16] [16]

and Krause, A

Golovin, D. and Krause, A. 2011. Adaptive submodularity:theory and applications in active learning and stochastic optimization. Journal of Artiﬁcial Intelligence Research 42 , 427–

work page 2011

[17] [17]

arXiv version (arxiv.org/abs/1003.3967) includes di scussions on the myopic feedback model

work page internal anchor Pith review Pith/arXiv arXiv

[18] [18]

, Nagarajan, V

Gupta, A. , Nagarajan, V. , and Singla, S. 2016. Algorithms and adaptivity gaps for stochastic probing. In SODA. SIAM

work page 2016

[19] [19]

, Nagarajan, V

Gupta, A. , Nagarajan, V. , and Singla, S. 2017. Adaptivity gaps for stochastic probing: Submodular and XOS functions. In SODA. SIAM

work page 2017

[20] [20]

, and Kawarabayashi, K.-I

Hatano, D., Fukunaga, T. , and Kawarabayashi, K.-I. 2016. Adaptive budget allocation for maximizing inﬂuence of advertisements. In IJCAI. 3600–3608

work page 2016

[21] [21]

, Kleinberg, J

Kempe, D. , Kleinberg, J. , and Tardos, ´E. 2003. Maximizing the spread of inﬂuence through a social network. In Proceedings of the ninth ACM SIGKDD . ACM, 137–146

work page 2003

[22] [22]

, Kleinberg, J

Kempe, D. , Kleinberg, J. M. , and Tardos, ´E. 2015. Maximizing the spread of inﬂuence through a social network. Theory of Computing 11, 4, 105–147. Conference version appeared in KDD’2003

work page 2015

[23] [23]

, Krause, A

Leskovec, J. , Krause, A. , Guestrin, C. , F aloutsos, C., V anbriesen, J. M. , and Glance, N. 2007. Cost-eﬀective outbreak detection in networks. In ACM Knowledge Discovery and Data Mining . 420–429

work page 2007

[24] [24]

, F an, J., W ang, Y., and Tan, K

Li, Y. , F an, J., W ang, Y., and Tan, K. 2018. Inﬂuence maximization on social graphs: A survey. IEEE Trans. Knowl. Data Eng. 30, 10, 1852–1872

work page 2018

[25] [25]

, Chen, W

Lin, Y. , Chen, W. , and Lui, J. C. 2017. Boosting information spread: An algorithmic approach. In ICDE. IEEE, 883–894

work page 2017

[26] [26]

, Chen, W

Lu, W. , Chen, W. , and Lakshmanan, L. V. 2015. From competition to complementarity: comparative inﬂuence diﬀusion and maximization. Proceedings of the VLDB Endowment 9, 2, 60–71

work page 2015

[27] [27]

, Zhang, Z

Lu, Z. , Zhang, Z. , and Wu, W. 2017. Solution of bharathi–kempe–salek conjecture for inﬂuence maximization on arborescence. Journal of Combinatorial Optimization 33, 2, 803–808

work page 2017

[28] [28]

Adaptive Influence Maximization with Myopic Feedback

Peng, B. and Chen, W. 2019. Adaptive inﬂuence maximization with myopic feedback . arXiv preprint arXiv:1905.11663

work page internal anchor Pith review Pith/arXiv arXiv 2019

[29] [29]

, Tziortziotis, N., and V azirgiannis, M

Salha, G. , Tziortziotis, N., and V azirgiannis, M. 2018. Adaptive submodular inﬂuence maximization with myopic feedback. In ASONAM. IEEE, 455–462. 12

work page 2018

[30] [30]

and Singer, Y

Seeman, L. and Singer, Y. 2013. Adaptive seeding in social networks. In FOCS. IEEE, 459–468

work page 2013

[31] [31]

Singer, Y. 2016. Inﬂuence maximization through adaptive seeding. ACM SIGecom Ex- changes 15, 1, 32–59

work page 2016

[32] [32]

, Kakimura, N

Soma, T. , Kakimura, N. , Inaba, K. , and Kawarabayashi, K.-i. 2014. Optimal budget allocation: Theoretical guarantee and eﬃcient algorithm. In ICML

work page 2014

[33] [33]

, Huang, W

Sun, L. , Huang, W. , Yu, P. S. , and Chen, W. 2018. Multi-round inﬂuence maximization. In KDD. ACM, 2249–2258

work page 2018

[34] [34]

, Shi, Y

Tang, Y. , Shi, Y. , and Xiao, X. 2015. Inﬂuence maximization in near-linear time: A martingale approach. In SIGMOD’15. ACM, 1539–1554

work page 2015

[35] [35]

, and Shi, Y

Tang, Y., Xiao, X. , and Shi, Y. 2014. Inﬂuence maximization: near-optimal time complex- ity meets practical eﬃciency. In SIGMOD’14

work page 2014

[36] [36]

Tong, G. , Wu, W. , Tang, S. , and Du, D.-Z. 2017. Adaptive inﬂuence maximization in dynamic social networks. IEEE/ACM Transactions on Networking (TON) 25, 1, 112–125

work page 2017

[37] [37]

Vondr´ak, J. 2007. Submodularity in combinatorial optimization

work page 2007

[38] [38]

, and Cui, L

W ang, A., Wu, W. , and Cui, L. 2016. On bharathi–kempe–salek conjecture for inﬂuence maximization on arborescence. Journal of Combinatorial Optimization 31, 4, 1678–1684

work page 2016

[39] [39]

and Tang, S

Yuan, J. and Tang, S. 2017. No time to observe: Adaptive inﬂuence maximization wi th partial feedback. In IJCAI. 13 Appendix For convenience, we restate the lemmas and theorems in the ap pendix before the proofs. A Missing Proofs from Section 3 Lemma 3.2. E [f (Ψ(1))] = F (1 −e−x1, · · ·, 1 −e−xn) ≤F (x1, · · ·,x n). Proof. Notice that in the Poisson proc...

work page 2017

[40] [40]

Lemma 4.3

( 26) ( 27), we complete the proof. Lemma 4.3. For any i, we have F1(0, · · ·, 0,x i, · · ·,x n) −F1(0, · · ·, 0,x i+1, · · ·,x n) = xipi (1 −Fi(0, · · ·, 0,x i+1, · · ·,x n)). Proof. Since the node 1’s predecessors form a directed line, for any i we have F1(0, · · ·, 0,x i, · · ·,x n) −F1(0, · · ·, 0,x i+1, · · ·,x n) =pi · (Fi(0, · · ·, 0,x i, · · ·,x n...

work page