summaryrefslogtreecommitdiff
path: root/quick-tech-report/rotohsm_tech_report.tex
blob: 41938f7ef70d858e7744bc0405726a524638763a (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
\documentclass[12pt,a4paper]{article}
\usepackage[english]{babel}
\usepackage[utf8]{inputenc}
\usepackage[T1]{fontenc}
\usepackage[
    backend=biber,
    style=numeric,
    natbib=true,
    url=false, 
    doi=true,
    eprint=false
    ]{biblatex}
\addbibresource{rotohsm.bib}
\usepackage{amssymb,amsmath}
\usepackage{listings}
\usepackage{eurosym}
\usepackage{wasysym}
\usepackage{amsthm}
\usepackage{tabularx}
\usepackage{multirow}
\usepackage{multicol}
\usepackage{tikz}
\usepackage{mathtools}
\DeclarePairedDelimiter{\ceil}{\lceil}{\rceil}
\DeclarePairedDelimiter{\paren}{(}{)}

\usetikzlibrary{arrows}
\usetikzlibrary{chains}
\usetikzlibrary{backgrounds}
\usetikzlibrary{calc}
\usetikzlibrary{decorations.markings}
\usetikzlibrary{decorations.pathreplacing}
\usetikzlibrary{fit}
\usetikzlibrary{patterns}  
\usetikzlibrary{positioning}
\usetikzlibrary{shapes}

\usepackage[binary-units]{siunitx}
\DeclareSIUnit{\baud}{Bd}
\usepackage{hyperref}
\usepackage{tabularx}
\usepackage{commath}
\usepackage{graphicx,color}
\usepackage{ccicons}
\usepackage{subcaption}
\usepackage{float}
\usepackage{footmisc}
\usepackage{array}
\usepackage[underline=false]{pgf-umlsd}
\usetikzlibrary{calc}
%\usepackage[pdftex]{graphicx,color}
\usepackage{epstopdf}
\usepackage{pdfpages}
\usepackage{minted} % pygmentized source code

\renewcommand{\floatpagefraction}{.8}
\newcommand{\degree}{\ensuremath{^\circ}}
\newcolumntype{P}[1]{>{\centering\arraybackslash}p{#1}}

\usepackage{fancyhdr}
\fancyhf{}
\fancyfoot[C]{\thepage}
\newcommand{\includenotebook}[2]{
    \fancyhead[C]{Included Jupyter notebook: #1}
    \includepdf[pages=1,
        pagecommand={\thispagestyle{fancy}\section{#1}\label{#2_notebook}}
        ]{resources/#2.pdf}
    \includepdf[pages=2-,
        pagecommand={\thispagestyle{fancy}}
        ]{resources/#2.pdf}
}

\begin{document}

\title{A High-Security Physical Security Primitive Based On Mechanical Movement}
\author{Jan Götte}
\date{2020-09-15}
\maketitle

\section{Abstract}
In this paper, we introduce a novel, highly effective countermeasure against physical attacks: Inertial hardware
security modules. Whereas conventional technology can be categorized into systems monitoring a thin boundary (such as
security meshes) and systems monitoring the interior volume (such as the "enclosure PUF" of Tobisch et al.). What all of
these systems have in common is that they try to detect attacks by crafting sensors responding to increasingly minute
manipulations of the monitored medium. Our approach is novel in that we alleviate the sensitivity requirement of a
security mesh by increasing the complexity of any manipulation at all by orders of magnitude by fastly rotating the
security mesh--presenting a moving target to an attacker. Attempts to modify the rotation itself are easily monitored
with commercial MEMS accelerometers and gyroscopes.

Our approach leads to a HSM that can easily be built from off-the-shelf parts by any university electronics lab, yet is
as secure or more secure than even the best commercial offerings.

\section{Introduction}
Since the early days of computers, physical security has often been a core component of any computer system's security
architecture. Physical security in fact predates our modern concept of computer security by decades. Long before
passwords, access control lists, role-based authentication and other modern concepts of information security were
developed, information was secured by physically locking away the computers that held it.

Nowadays, concerns of physical security are mostly limited to certain applications. Credit card processing and medical
data processing are two instances where a combination of smartcards and hardware security modules is used to provide a
higher level of security than what ordinary computers can provide. Meanwhile, in most commercial data processing
applications, the physical security provided by an average datacenter is considered to be appropriate.

In modern systems, phyiscal security always is tightly interwoven with the system's overall security architecture.
Beyond the level provided by locks and guards, it is generally considered infeasible to physically secure all parts of a
computer. High-level physical security is usually limited to either a single chip or part of a chip such as a secure
element, enclave or smartcards--or it is limited to a small module acting within a very limited scope, as is the case in
commercial HSMs that largely act as cryptographic co-processors with built-in key management functions.

\subsection{Technical approaches to physical security}
The use of chips as secure elements has recently become popular beyond the smartcards of yesteryear. Apple has carried
over a secure enclave IC from their line of phones into their line of laptops in 2016. Likewise, Google has developed
its own security IC for use in phones and laptops. An issue to consider with all such IC-based security solutions is
that they do not provide any cryptographic security. The real-world security of these solutions solely rests on the
assumption that due to their fine structure, ICs are hard to reverse engineer and manipulate. As of now, this property
holds and in the authors' opinion it will likely be a reasonable assumptions for some years to come. However, in its
essence this is a type of security by obscurity: Obscurity here mostly applying to the rarity of tools that are
necessary for practical attacks such as focused ion beam workstations and accompanying sample preparation equipment. An
important observation in this regard is that already, several people are slowly chipping away at this obscurity: A group
at Ruhr University Bochum is working on advanced tooling for netlist reverse engineering, and there are several
companies offering commercial IC reverse engineering services.

\subsection{Hardware Security Modules}
At larger physical dimensions, hardware security modules (HSMs) provide an effective solution to the problem: In
conformity with Kerckhoff's principle, their creators do not try to hide the structure of the system within. Instead,
the HSM monitors it for any manipulation and wipes all key material when one is detected. The most common commercial
realization of this is what we call a "boundary-monitoring" HSM. This is a device uses a microcontroller monitoring the
conductivity of usually two electrical traces that are folded many times to cover the entire area of a plastic enclosure
part or a plastic foil wrapped around the module. The security problem thus gets transformed into a manufacturing
challenge: How fine can these traces be made--so they are disturbed by even the tiniest of holes for say, a fine needle;
and how sensitive can they be made to perturbations--so they break from even gentle attempts at mechanical, chemical or
other physical manipulation.

The other type of HSM that so far has garnered mostly academic interest are what we call "volumetric" HSMs. Where a
boundary-monitoring HSM senses disturbations to a thin boundary between its inside and the outside world, a volumetric
HSM monitors its entire interior volume. Approaches that have been proposed so far include monitoring using
electromagnetic radiation % FIXME: citation (paper1 (this chip thing w/ distributed PAs/LNAs), paper2 (RUB)
and ultrasonic sensing. % FIXME: citation
Common to both approaches is that for technical reasons the wavelength of the employed radiation is in the range of
millimeters or larger. This implies that practical attacks acting on a smaller scale of physical size require sensitive
monitoring circuity to be reliably caught. % FIXME maybe talk to a physicist here.
Since they require advanced transceivers and signal processing, these HSMs incur a high implementation cost compared to
one based on a traditional security mesh, while they in turn promise to be easier and less expensive to scale in
physical size. A severe problem with any previous volumetric designs is that their security analysis is very hard. While
multiple designs have been proposed academically, none of these proposals include an analysis of their physical security
properties that goes beyond guesswork. %FIXME verify this.
The obvious reason for this is that to evaluate the volume inside the HSM that is covered by a given transceiver
combination and a given test signal pattern necessarily requires numerically solving the volumetric electromagnetic
field equations inside the HSM, applying a model of transmitter and receiver to the results that takes into account
receiver sensitivity and ADC resolution, transmitter power and receiver saturation effects and then validating that
every point in space (or at least inside a boundary region) is covered. While the guess that attacks are impractical
might still be true this would be based on the fact that the same problem presents itself to an attacker trying to
circumvent these measures--degrading their security to simple obscurity again.

\subsection{Inertial HSMs: A new approach to physical security}
We are certain that there is still much work to be done and many insights to be gained from further explorations
of the two concepts described above. Trivially, consider a box with mirrored walls that, suspended on thin wires,
contains a smaller box that has cameras looking outward in all directions at the mirrored walls. Given that the defender
can control lighting conditions inside this kaleidoscopic box in this application modern cameras can be considered
equivalent to or better than the human eye. Thus, a successful physical attack on this system would likely an
"invisibility cloaks"--and the system would remain secure as long as no such thing exists. This example is a useful
point of reference. To be viable, a HSM technology must be either smaller or more sensitive than such a setup.

The candidate we wish to introduce in this paper uses a novel approach to side-step the issues of both the concepts
introduced in the previous section and provides radically better security against physical attacks--both in theory and
in practice.

Our core observation is that given any less expensive but more coarse HSM technology, we can make it radically more
difficult to attack by introducing fast mechanical motion. As a trivial example, consider a HSM as it is used in
ecommerce applications for credit card payments. Focusing on its main defense for simplicity, its physical security is
limited by the structure size of the mesh that is likely used in its shell. If an attacker can tap the mesh's electrical
traces and bridge across the mesh in a way the HSM cannot detect (e.g. by making sure the bridge has the same electrical
impedance as the mesh traces have e.g. by comparing against another device of the same type), they have circumvented the
device's protections. Any such attack would likely involve some fine drill bits, needles, wires, glue, perhaps solder or
even lasers.

Now consider the same HSM, but this time mounted on a large flywheel. In this scenario the HSM uses the same
protections as before, but is now additionally equipped with an accelerometer that it uses to verify that it is in fact
rotating at a very high speed. How would an attacker approach this HSM? They would have to either slow down the rotation
(which would quickly be sensed by the accelerometer) or they would have to attack the moving HSM--the HSM literally
becomes a moving target. While rotating the entire attack workbench might be possible for slow speeds, rotating frames
of reference quickly become inhospitable to human life and at some point the technical means to rotate a CNC attack
robot probably weighing several kilograms become inconvenient as well. Contact-less EM or optical attacks are more
limited in the first place, and can effectively be shielded.

\subsection{Contributions}
This work contains the following contributions:
\begin{enumerate}
    \item Presentation of the \emph{Inertial HSM} concept, allowing cost-effective prototype and small-scale production
        of highly secure HSMs.
    \item Discussion of possible boundary sensing modes in the intertial HSM model.
    \item Exploration of the design space of inertial HSMs.
    % FIXME \item Presentation of a prototype inertial HSM.
    % FIXME \item Measurement of the prototype HSM's susceptibility to various types of attack.
\end{enumerate}

\section{Related work} 
% summaries of research papers on HSMs.
% I have not found any actual prior art on anything involving mechanical motion beyond ultrasound.
In chapter 18 of the forthcoming 3rd edition of his seminal book on "Security Engineering"\cite{anderson2020}, Ross
Anderson gives a background on physical security in general and on HSMs in particular. As an example he cites the IBM
4758 HSM whose details are laid out in depth in \cite{smith1998}. This HSM is an example of an industry-standard
construction. Though it is now a bit dated, the construction techniques of the physical security mechanisms have not
changed much in the last two decades. Apart from some auxiliary temperature and radiation sensors to guard against
attacks on the built-in SRAM memory the module's main security barrier uses the traditional construction of a flexible
mesh wrapped around the module's core. In \cite{smith1998}, the authors claim the module monitors this mesh for
short circuits, open circuits and conductivity. The fundamental approach to tamper detection and construction is similar
to other commercial offerings\cite{obermaier2018}.

In \cite{immler2019}, Immler et al. describe a HSM based on precise capacitance measurements of a mesh. In contrast to
traditional meshes, the mesh they use consists of a large number of individual traces (more than 32 in their example).
Their concept promises a very high degree of protection. The main disadvantages of their concept are a limitation in
both covered area and component height, as well as the high cost of the advanced analog circuitry required for
monitoring. A core component of their design is that they propose its use as a PUF to allow for protection even when
powered off, similar to a smart card--but the design is not limited to this use.

In \cite{tobisch2020}, Tobisch et al.\ describe a construction technique for a hardware security module that is based
around commodity Wifi hardware inside a conductive enclosure. In their design, an RF transmitter transmits a reference
signal into the RF cavity formed by the conductive enclosure. One or more receivers listen for the signal's reflections
and use them to characterize the RF cavity w.r.t.\ phase and frequency response. Their fundamental assumption is that
the RF behavior of the cavity is inscrutable from the outside, and that even a small disturbance anywhere within the
volume of the cavity will cause a significant change in its RF response. The core idea in \cite{tobisch2020} is to use
commodity Wifi hardware to reduce the cost of the HSM's sensing circuitry. The resulting system is likely both much
cheaper and capable of protecting a much larger security envelope than e.g. the design from \cite{immler2019}, at the
cost of worse and less predictable security guarantees.

While \cite{tobisch2020} approach the sensing frontend cost as their only optimization target, the prior work of Kreft
and Adi\cite{kreft2012} considers sensing quality. Their target is an HSM that envelopes a volume barely larger than a
single chip. They theorize how an array of distributed RF transceivers can measure the physical properties of a potting
compound that has been loaded with RF-reflective grains. In their concept, the RF response characterized by these
transceivers is shaped by the precise three-dimensional distribution of RF-reflective grains within the potting
compound.

\subsection{Comparison to prior research}

Our concept is truly novel in that neither academic literature, nor patent databases contain any mention of mechanical
motion being used as part of a hardware security module. Most academic research concentrates on the issue of creating
new, more sensitive security barriers for HSMs while commercial vendors concentrate on means to cheaply manufacture
these security barriers. Our concept instead focuses on the issue of taking any existing, cheap low-performance security
barrier and transforming it into a marginally more expensive but very high-performance one. The closes to a mechanical
HSM that we were able to find during our research is an 1988 patent\cite{rahman1988} that describes an mechanism to
detect tampering along a communication cable by enclosing the cable inside a conduit filled with pressurized gas.

\section{Intertial HSM construction and operation}
\subsection{Using motion for tamper detection}
Mechanical motion has been proposed as a means of making things harder to see with the human eye\cite{haines2006} but we
seem to be the first to use it in tamper detection. Let us think about how one would go about increasing the security of
a primitive tamper detection sensor.

\begin{enumerate}
    \item We need the sensor's motion to be fairly fast. If any point of the sensor moves slow enough for a human to
        follow, it becomes a weak spot.
    \item We need the sensor's motion to be periodic to keep it within a reasonable space. Otherwise we could just load
        our HSM on an airplane and assume that airplanes are hard to stop non-destructively mid-flight.
    \item We need the sensor's motion to be very predictable so that we can detect an attacker trying to stop it.
\end{enumerate}

From this, we can make a few observations.

\begin{enumerate}
    \item Linear motion is likely to be a poor choice since it requires a large amount of space, and it is comparatively
        easy to follow something moving linearly.
    \item Oscillatory motion such as linear vibration or a pendulum motion might be a good candidate, but for the
        instant at its apex when the vibration reverses direction the object is stationary, which is a weak spot.
    \item Rotation is a very good choice. Not only does it not require much space to execute, but also if the axis of
        rotation is within the HSM itself, an attacker trying to follow the motion would have to rotate around the same
        axis. Since their tangential linear velocity would rise linearly with the radius from the axis of rotation, an
        assumption on tolerable centrifugal force allows one to limit the approximate maximum size and mass of an
        attacker. For an HSM measuring at most a few tens of centimeters across, it is easy to build something that
        rotates too fast for a human to be able to follow it. The axis of rotation is a weak spot, but this can be
        alleviated by placing additional internal sensors around it and locating all sensitive parts of the sensing
        circuit radially away from it.
\end{enumerate}

Another important observation is that we do not have to move the entire contents of the HSM. It suffices if we can
somehow move the tamper detection barrier around these contents while keeping the contents stationary. This reduces the
inertial mass of the moving part and eases data communication and power supply of the payload.

In a rotating reference frame, at any point the centrifugal force is proportional to the square of the angular frequency
and linearly proportional to the distance from the axis of rotation. We can exploit this fact to create a sensor that
detects any disturbance of the rotation by simply placing a linear accelerometer at some distance to the axis of
rotation. During constant rotation, the linear acceleration tangential to the rotation will be zero. The centrifugal
force is orthogonal to this, and will be constant as long as the angular velocity remains constant (assuming a fixed
axis of rotation). At high angular velocities, considerable forces can be created this way. This poses the engineering
challenge of preventing the whole thing from flying apart, but also creates an obstacle to any attacker trying to
manipulate the sensor.

\subsection{Payload mounting mechanisms}
The simplest way to mount a stationary payload in a rotating security mesh is to drive the rotor through a
hollow axis. This allows the payload to be mounted on a fixed rod threaded through the hollow axis, along with wires for
power and data.

\subsection{Rotating mesh power supply}
There are several options to transfer power to the rotor from its stationary frame.

\begin{enumerate}
    \item Slip ring contacts are a poor candidate as they are limited in their maximum speed and lifetime, and as
        precision mechanical components are expensive.
    \item Inductive power transfer as used in inductive charging systems can be used without modification.
    \item A second brushless motor on the axis of rotation can be used as a generator, with its axis connected to the
        fixed frame and its stator mounted and connected to the rotor.
    \item A bright LED along with some small solar cells may be a practical approach for small amounts of energy.
    \item For a very low-power security mesh, a battery specified to last for the lifetime of the device may be
        practical.
\end{enumerate}

\subsection{Rotating mesh data communication}
As we discussed above, while slip rings are the obvious choice to couple electrical signals through a rotating joint,
they are likely to be too expensive and have too short a life span for our application. Since the only information that
needs to pass between payload and rotor are the occassional status report and a high-frequency heartbeat signal that
acts as the alarm trigger, a simple optocoupler close to the axis of rotation is a good solution.

\section{Future work}
With this paper, we intend to spread the word on our idea. Thus, below we include a selection of the open questions we
are currently working on. If you wish to tackle some of these, please feel free to contact the authors.

\subsection{Other modes of movement}
Though we decided to use rotation as an easy-to-implement yet secure option, other modes of movement bear promise as
well. Particularly for less high-security applications without strict space constraints, a variant based on a pendulum
motion may be worth investigating as it would simplify the mechanical construction. Power and data transfer to the
moving part could simply be done with very flexible cables.

\subsection{Multiple axes of rotation}
One option to alleviate the weak spot a rotating mesh has at its axis of rotation, a system with two or more axes of
rotation could be used. A single mesh would still suffice in this case, but when evaluating accelerometer readings, the
braking detection algorithm would have to superimpose both.

\subsection{Means of power transmission}
Power transmission from payload to rotor is another point worth investigating. It may be possible to use some statically
mounted permanent magnets with a coil integrated into the rotor's PCB as a low-power generator. While likely
inefficient, this setup would be low-cost and would still suffice for the meager power requirements of the rotor's
monitoring circuitry.

\subsection{Payload cooling}
An issue with existing HSM concepts is that the mesh has to fully envelope the payload, and thus traditional air cooling
or heat pipes cannot be used. Existing systems rely on heat conduction through the mesh alone for cooling, severly
limiting the maximum power dissipation of the payload. In our rotating HSM concept, the rotating mesh can have radial
gaps in the mesh without impeding its function. This allows air to pass through the mesh during rotation, and a future
evolution of the concept could even integrate a fan into the rotating component. This greatly increases the maximum
possible power dissipation of the payload, allowing for much more powerful processing.

\subsection{Other sensing modes}
Since the security requirement the primary tamper-detection barrier needs to measure up to are much more lenient in the
rotating HSM concept than in traditional HSMs, other coarse sensing modes besides low-tech meshes may be attractive. One
possibility that would also eliminate the need of any active circuitry on the rotor would be to print the inside of the
rotor with a pattern, then have a linear array of reflective optical sensors located close to the rotor along a
longitudinal line. These sensors would observe the printed pattern passing by at high speed, and could compare their
measurements against a model of the rotor. Tampering by drilling holes or slots would show up as adding an offset to
part or all of the pattern. Likewise, the speed of rotation can be deducted directly from a sequence of measurements.

\subsection{Longevity}
A core issue with a mechanical HSM is component longevity. Save for dust and debris clogging up the system's mechanics
the primary failure point are the bearings. A good partner for further development or even commercialization might be a
manufacturer of industrial ducted fans as they are used e.g.\ in servers for cooling. Small industrial fans usually use
BLDC motors and bearings specially optimized for longevity.

\subsection{Transportation of an active device}
A rotating mass responds to torque not co-linear with its axis of rotation with a gyroscopic precession force. In
practice, this means that moving a device containing a spun-up rotating HSM on its inside might induce significant
forces on both the HSM (posing the danger of false alarms) and on the carrier of the device (potentially making handling
challenging). This effect would have to be taken into account in a real-world deployment, especially if the finished
device is to be shipped by post or courier services after spin-up.

\subsection{Hardware prototype}
We are currently working on a hardware prototype that demonstrates the fundamental components of our concept. The
prototype will be based on a security mesh made with a commercial printed circuit board manufacturing process. In our
prototype we intend to use two commercially available hollow-shaft brushless DC (BLDC) motors originally intended for
quadcopter-mounted camera gimbals, one for driving and one for power transfer. The prototype will have a usable internal
volume sufficient to house a small form factor PC ($\approx\SI{2}{\liter}$).

\section{Attacks}
\subsection{Attacks on the mesh}
There are two locations where one can attack a tamper-detection mesh. Either, the mesh itself can be tampered with. This
includes bridging its traces to allow for a hole to be cut. The other option is to tamper with the monitoring circuit
itself, to prevent a damaged mesh from triggering an alarm and causing the HSM to erase its contents. Attacks in both
locations are electronic attacks, i.e. they require electrical contact to parts of the circuit. Traditionally, this
contact is made by soldering, or by placing a probe such as a thin needle. Any kind of electrical contact that does not
involve an electron or ion beam or a liquid requires mechanical contact. We consider none of these forms feasible to be
performed on an object rotating at high speed without a complex setup that rotates along with the object. Thus, we
consider them to be practically infeasible outside of a well-funded, special-purpose laboratory.

\subsection{Attacks on the alarm circuitry}
An electronic attack could also target the alarm circuitry inside the stationary payload, or the communication link
between rotor and payload. The link can easily be proofed by using a cryptographically secured protocol along with a
high-frequency heartbeat message. The alarm circuitry has to be designed such that it is entirely contained within the
HSM's security envelope and has to tolerate environmental attacks such as through temperature, ionizing radiation,
lasers, supply voltage variations, ultrasound or other vibration and gases or liquids. The easiest way to proof an alarm
system against these is to employ adequate filtering of the incoming power supply and use sensors for the others,
triggering an alarm in case extraordinary environmental variations are detected.

\subsection{Fast and violent attacks}
A variation of the above attacks on the alarm circuitry would be an attack that attempts to simply destroy this
circuitry before the alarm can be acted upon. This type of attack might involve things such as a large hammer, or a gun.
Mitigations for this type of attack include putting the entire payload and monitoring circuit in a mechanically robust
enclosure and potting them, and linking all components of the alarm chain in such a way cryptographically and on a
protocol level that the destruction of any of its parts leads to the secrets being destroyed before an attack would be
able to probe them. An implication of this is that the electrical realization of the alarm signal up to its eventual
destination cannot be a simple active-high or active-low line, since neither can be considered fail-safe in this
scenario.

\subsection{Attacks on the rotation sensor}
An attacker trying to stop the rotor to tamper with the mesh may first try to deceive the rotation monitoring circuit
such that it misses the rotor being stopped. In a realization based on a commercial MEMS accelerometer, this attack
could take two forms: An electronic attack on the MEMS sensor, the monitoring microcontroller or the link in between,
and a physical attack on the MEMS sensor itself. The former would be no easier than an electronic attack that attempts
to bridge the mesh traces at the monitoring microcontroller. Thus, we consider it not to be practically feasible outside
of a laboratory built especially for this purpose.

There are several options for the latter attack. A recent paper %FIXME
has shown that accelerometers respond to certain ultrasonic stimuli with bogus measurements. Since this primitive does
not, however, yield accurate control over these bogus measurements, we deem it to be impractical for our scenario.
Another possible attack scenario would be to somehow stop the rotating motion while subjecting the HSM to an external
linear motion. Given the low error margins in the measurements of commercial accelerometers we consider this attack
infeasible. A last type of attack might be to try to physically tamper with the accelerometer's sensing mechanism. MEMS
accelerometers usually use a simple cantilever design, where a proof mass moves a cantilever whose precise position can
be measured electronically. A possible way to attack such a device might be to first decapsulate it using laser ablation
synchronized with the device's rotation. Then, a fast-setting glue such as a cyanoacrylate could be deposited on the
moving MEMS parts in either liquid or gaseous form, locking them in place after hardening. This attack would require
direct access to the accelerometer from the outside and can be prevented by mounting the accelerometer inside the
security envelope. This attack only works if the rate of rotation is constant and is trivially detectable if the rate of
rotation is set to change on a schedule.

\section{Conclusion}
In this paper, we have presented inertial hardware security modules, a novel concept for the construction of highly
secure hardware security modules from inexpensive, commonly available parts. We have elaborated the engineering
considerations underlying a practical implementation of this concept. We have analyzed the concept for its security
properties and highlighted its ability to significantly strengthen otherwise weak tamper detection barriers. We have
laid out some ideas for future research on the concept, and we will continue our own research on the topic.

\printbibliography[heading=bibintoc]
\appendix
\section{Patents and licensing}
During devlopment, we performed several hours of research on prior art for the inertial HSM concept. Yet, we could not
find any mentions of similar concepts either in academic literature or in patents. Thus, we deem ourselves to be the
inventors of this idea and we are fairly sure it is not covered by any patents or other restrictions at this point in
time.

Since the concept is primarily attractive for small-scale production and since cheaper mass-production alternatives are
already commercially available, we have decided against applying for a patent and we wish to make it available to the
general public without any restrictions on its use. This paper itself is licensed CC-BY-SA (see below). As for the
inertial HSM concept, we invite you to use it as you wish and to base your own work on our publications without any fees
or commercial restrictions. Where possible, we ask you to cite this paper and attribute the inertial HSM concept to its
authors.

\center{
    \center{\ccbysa}

    \center{This work is licensed under a Creative-Commons ``Attribution-ShareAlike 4.0 International'' license. The
    full text of the license can be found at:}

    \center{\url{https://creativecommons.org/licenses/by-sa/4.0/}}

    \center{For alternative licensing options, source files, questions or comments please contact the authors.}

    \center{This is version \texttt{\input{version.tex}\unskip} generated on \today. The git repository can be found at:}

    \center{\url{https://git.jaseg.de/rotohsm.git}}
}
\end{document}