Milli 5 User Manual

 

MILLITM 5 PRODUCT DATA SHEET KEY BENEFITS Integrates with Silver Spring Networks mesh networking technology Long range Low power (+23dBm output power) and small form factor Support for IPv6, RFC 7252 Constrained Application Protocol (CoAP), and Wi-SUN 802.15.4g radio Security with standard cryptographic algorithms and PKI-based implementation Bi-directional communications OTA firmware updates The Silver Spring Networks Milli 5 is a wireless communications module optimized for battery-powered devices enabling the Internet of Important ThingsTM. The Milli 5 leverages Silver Spring Networks proven, self-forming, self-healing networking capabilities to bring connectivity to a new class of IoT devices. The small form factor and power-optimized design brings secure, reliable two-way integrated IPv6 connectivity to critical infrastructure. Silver Spring Networks Technology Silver Spring Networks provides autonomous wireless communication to geographically distributed devices, utilizing onboard firmware to securely communicate and interoperate with compatible wireless nodes to form a wireless mesh network. Silver Spring employs frequency hopping techniques to hop through frequency channels in unlicensed spectrum available worldwide. Each node hops in a pseudo-random hopping sequence, meaning each node synchronizes with other nodes in order to communicate on the network. Silver Spring utilizes time-based synchronization based upon a common time propagated through the network as a resource. Upon boot-up, Silver Spring devices enter acquisition mode, where they scan the available frequencies for discovery beacons. The discovery beacon contains the information necessary to synchronize their frequency-hopping. A host is any device to which the communications module is connected. A host application is any application that runs on that host. Silver Spring Networks IPv6 mesh is designed to mitigate unnecessary traffic as much as possible to reduce the probability for interference, excessive noise floor, and other deleterious RF effects that typically occur when unnecessarily chatty protocols are usedthat is, those with excessive keep-alive, polling, and other messages being broadcast continually. Each node is capable of dynamically identifying alternate routes SPECIFICATIONS Radio and Networking Capabilities Operates in 870-875.6 and 902-

928 MHz RF output power: 200 mW (+23 dBm) ARM Cortex-M3 32bit-

processing for low power 50 kbps data rate Security Assurance Certificatebased applayer protocol authentication

(ECDSA) Data Confidentiality (AES128) Firmware validation (ECDSA) Link Layer (AES128) Hardware Interfaces Available F/W currently supports CoAP over UART Please contact Silver Spring Networks about the roadmap for support of other interfaces or if your application requires a different interface. if required due to outages, link failures or other conditions. This leads to an extremely resilient network topology compared to other star topologies. The (logical) network topology of a battery mesh. The nodes in the diagram represent logical positions (not physical locations) in the battery mesh routing tree. How Milli 5 Battery Meshing Works In a battery-powered device, Milli 5 operates off the hosts power supply. To conserve power, Milli 5 spends most of its time sleeping. (Nodes sleep when not otherwise occupied with operations.) Milli 5 sleeps at about 1.4A or ~0.3 Joules/day. During installation, batterypowered devices (BPDs) perform an aggressive discovery of other BPDs or constantly powered devices (CPDs). Thereafter, BPD nodes wake up periodically and listen in a receive window. The energy required for receiving is approximately 3mJ/

second. Upon powerup, Milli 5 listens periodically for discovery packets from CPD/

BPD. These are used to establish time synchronization and establish the node on the network. Physical Specifications Parameter Size Weight Package Type Material Value 30x25x2.5mm 5g (approximately) LGA 72 pins PCB Board Electrical Specifications This section contains electrical specifications for Milli 5. Note: All specifications are subject to change without notice. Absolute Maximum Ratings: Under no circumstances must the absolute maximum ratings be violated. Stress exceeding one or more of the limiting values may cause permanent damage to the device. Parameter Supply voltage Voltage on any digital pin Input RF level VSWR limit Storage temperature range Reflow soldering temperature ESD Value Conditions All supply pins must have the same voltage -0.3 to 3.6

-

-

At antenna port

-

According to IPC/JEDEC J-STD-020 Human Body Model Charged Device Model (RF pins) Charged Device Model (non-RF pins)

-0.3 to VDD+0.3, max 3.6

+10 10:1

-40 to +120 260 250 250 250 Unit V V dBm C C V Recommended Operating Conditions Parameter Ambient temperature range Supply voltage Input voltage Conditions 0-95% RH

-

Do not exceed the absolute maximum voltage

-

-

Ripple Transient Min

-40 3.1

-0.3

-

-

Max 85 3.6 VDD +0.3 10 20 Unit C V V mV mV Power Consumption Parameter Sleep/Power-down RF channel sense Power Consumption Radio RX Power Consumption Radio TX 172 Typ

~ 10 A target goal (RTC and SRAM retention)

~2 7 Max

-

-

-

200 Unit A mA mA mA Conditions 32 kHz clock running, MCU register retention, full RAM retention

-

RX sniff mode, searching for packet

-

Receive Parameters Min Parameter Sensitivity Blocking Spurious Emissions Image Rejection

-

40

-

-

Transmit Parameters Parameter Output power highest setting Output power lowest setting Typ

-104 50

-55 50 Min 20

-3 Max

-

-

-

-

Units dBm dB dBm dB Conditions (870 - 875.6 and 902 - 928 Mhz) 10% PER and 50 kbps 200 & 400kHz channels (802.15.4g)

< 1 GHz FW controlled image rejection optimized TYP 22 0 Max 23 5 Conditions dBm dBm DEVELOPER PORTAL Milli-based Arduino Shield kits are available to develop IoT applications. The kits can be purchased at Silver Springs developer portal:

developer.ssni.com to start POC (Proof Of Concept) projects. This developer portal has the required documentation to get started with the kit, download and recreate reference applications, establish endtoend connectivity from the sensors to the back office data platform, interact with other users through forums, and create support tickets to get help. Signal Interface The Silver Spring Networks Milli 5 is an SMT reflow Land Grid Array (LGA) module with I/O and power connections at the bottom. Milli 5 Block Diagram A B C D E F A B C D E F Mechanical Specifications Note: The ground pads on the modules bottom side must be connected to electrical and thermal performance. 1 2 3 4 5 6 7 8 THIS DRAWING HAS BEEN GENERATED BY A CAD SYSTEM. CHANGES SHALL ONLY BE INCORPORATED AS DIRECTED BY THE DESIGN ACTIVITY. DO NOT REVISE MANUALLY. REV CHANGE NUMBER REVISIONS DESCRIPTION 01 INITIAL RELEASE BY TH DATE 3.28.17 SILVER SPRING NETWORKS PROPRIETARY INFORMATION THIS DOCUMENT IS THE SOLE PROPERTY OF SILVER SPRING NETWORKS. THE RELEASE OF DATA OR IN PART, WITHOUT THE WRITTEN PERMISSION OF SILVER SPRING NETWORKS ARE PROHIBITED. CONTAINED IN THIS DOCUMENT AND THE REPRODUCTION OF THIS DOCUMENT, IN WHOLE 22.750 15.750 8.750 19.250 12.250 5.250 1.750 22.750 19.250 15.750 12.250 8.750 5.250 1.750 CL 11.000 22.000 29.008 43 42 69 57 1 2 56 A 28 29 65 61 14 15 CL 4.250 2.00 17.500 4.250 23.983 1.14 54 55 56 1.78 3.00 2.00 57 3.00 1 2 3 1.78 D 1.14 DETAIL A SCALE 10:1 230 W Tasman Drive, San Jose, CA 95134 Phone : 1.866.204.0200 Fax : 1.866.776.0015 www.silverspringnetworks.com DOWNLOADED AND/OR HARDCOPY UNCONTROLLED UNLESS OTHERWISE SPECIFIED INTERPRET DRAWING IAW ASME Y14.100-2000. DIMENSIONING & TOLERANCING IAW ASME Y14.5M-1994. PARENTHETICAL INFORMATION FOR REFERENCE ONLY. DIMENSIONAL LIMITS APPLY AFTER PROCESSES. DIMENSIONS ARE IN MM (METRIC). TOLERANCES ARE: ANGLES 1 2 PLACE DECIMAL .13 3 PLACE DECIMAL .013 1.6 SURFACE FINISH (AVERAGE) REMOVE ALL BURRS AND SHARP EDGES .25 RAD MAX. CONCENTRICITY MACHINED DIA: .05 FIM MACHINED TOOL MISMATCH .05 MAX. DO NOT SCALE DRAWING THIRD ANGLE PROJECTION APPROVALS DESIGNER :

ENGINEER :

T.HUYNH MFG. ENGR. :

Q.A. :

PROG. MGMT/MKT :

DATE

-

3/28/2017

-

-

-

DOCUMENT, FOOTPRINT, LAYOUT, SIZE B SCALE:

CAGE NO. 5:1 MNIC MILLI 5 DWG NO. 800-0251-00 01 SHEET 1 OF 2 REV. 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 30.000.13 3.60 3.20 25.000.13 TOP VIEW 1.03 DIMENSIONS IN MILLIMETERS TOLERANCES:

0.00 =

0.000 =

.13

.013 PIN 29 16X 3.00 56X 1.00 14X 24.250 5X 21.250 2X 16.750 2X 12.500 2X 8.250 5X 3.750 14X 0.750 PIN 15 0 0 0

. 6 2 X 5 0 0 5

. 0 2 X 2 0 0 0

. 5 1 X 2 0 0 5

. 9 X 2 0 0 0

. 4 X 5 PIN 69 PIN 43 2X 23.875 2X 22.125 2X 20.375 2X 18.625 2X 16.875 2X 15.125 2X 13.375 2X 11.625 2X 9.875 2X 8.125 2X 6.375 2X 4.625 2X 2.875 2X 1.125 0 PIN 56 PIN 57 PIN 1

. 0 5 2 9 2 X 4 1

. 5 7 3 6 2 X 2

. 5 2 6 4 2 X 2

. 5 7 8 2 2 X 2

. 5 2 1 1 2 X 2

. 5 7 3 9 1 X 2

. 5 2 6 7 1 X 2

. 5 7 8 5 1 X 2

. 5 2 1 4 1 X 2

. 5 7 3 2 1 X 2

. 5 2 6 0 1 X 2

. 5 7 8 8 X 2

. 5 2 1 7 X 2

. 5 7 3 5 X 2

. 5 2 6 3 X 2 0

. 0 5 7 0 X 4 1 BOTTOM VIEW SIZE B SCALE:

CAGE NO. 5:1 DWG NO. 800-0251-00 01 SHEET 2 OF 2 REV. 1 2 3 4 5 6 7 8 Mechanical dimensions and land pattern Pin 1 Identification On the top side, Milli 5 has a 2D barcode to identify MAC address, part number, and other key product data that is needed. The pinhole also represents the Pin 1 corner on the Milli 5 assembly. Note: The horizontal flips bottom pins 180. A B C E F A B C D E F Pin Assignments and Signal Description The Milli 5 module provides connecting pads to integrate the module into external applications. Figure below shows the pin assignments and Table 1 lists the pins and signal descriptions. Note that pin assignments are preliminary and might change at a later date. Pin assignments Note: Pins marked NC (no connect) can be soldered but must be left open, and not be connected to an external application. It is highly recommended that all pads be soldered. Pins and signal descriptions Pin Number Signal Name Input/Output Description 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 3V3 GND TXD RXD SCL SDA MISO-GPIO_16 MOSI_GPIO_17 SCK_GPIO_18 GPIO_29_SSEL NC (Test RSV) NC (Test RSV) GPIO_23_ADC1 GPIO_26_ADC4 GND RF900 GND GPIO_27_ADC5 ATEST1_ADC3 ATEST0_ADC2 GND 3V3RF GND GND NC GND GND NC GND NC NC NC Power Power Output Input Output I/O I/O I/O I/O I/O I/O I/O I/O I/O Power I/O Power I/O I/O I/O Power Input Power Power N/A Power Power N/A Power N/A N/A N/A 3.1V 3.6V main module supply Ground UART interface, RXD/TXD (Serial Interface) communications (up to 115,200 bps, 8-N-1) UART interface, RXD/TXD (Serial Interface communications (up to 115,200 bps, 8-N-1) NC NC NC NC NC NC NC NC NC Add 10K or bigger pullup resistor and connect to 3.3V Ground RF I/O port, 50 ohm nominal Ground NC NC NC Ground NC Ground Ground NC Ground Ground NC Ground NC NC NC Pin Number Signal Name Input/Output Description 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57-72 NC GND NC NC GPIO_5 NC GPIO_8 GND NC GPIO_6 GND GPIO_7 NC GND NC NC GND NC NC NC RSET_N GND NC 3V3 GND N/A Power N/A N/A I/O N/A Output Power N/A I/O Power Input N/A Power N/A N/A Power N/A N/A N/A Input Power N/A Power Power NC Ground NC NC Interrupt pin Pin to wake up host processor from Milli 5 NC Is an open collector pin that Milli 5 would pull low to affect the host device to reset. Ground NC NC Ground Interrupt pin - wakes up Milli 5 so host processor can send data NC Ground NC NC Ground NC NC NC Milli 5 module master reset. Active low input. When asserted, all outputs will be made high impedance Ground NC 3.1V 3.6V main module supply Ground

* Pins 316 are bidirectional, inputs are pull up/pull down, and outputs are configurable as pushpull or open drain. Drive capacity varies with pin. 50 ohm PCB Design Guidelines Antenna design and RF layout are critical in a wireless system that transmits and receives electromagnetic radiation in free space. The Milli 5 module does not include an antenna connector. The antenna (or unique antenna connector) must be connected to Milli 5 via a transmission line implemented on the host PCB. SSN recommends the use of a co-planer Waveguide to minimize space and board real estate. The PCB trace should be kept as short as possible to minimize path loss. IPC 6011 and IPC 6012 Class 2 or better PCB manufacturing practices must be followed to ensure repeatable results. The transmission line trace will be bounded on both sides by a ground reference plane. For EMI considerations this ground plane should be extended and connected to other ground layers, one of which is on the opposite side of the PCB. The opposite side ground plane shall be contiguous under the trace and shall extend beyond the trace. These ground planes should be stitched together using vias spaced 40-50 mils (2 mm) apart. Avoid breaking up these ground planes by routing traces through them. Avoid routing any other signal traces, especially high speed digital signals, near the transmission line. Locate the transmission line trace away from power supply lines and power supply regulatory circuitry. Key design parameters The antenna trace must have a characteristic impedance of 50 5%. The recommended dimensions and the Gerber layout for the antenna trace are provided on the following pages. To calculate the key parameters requires calculating transmission line parameters. Although there are many transmission line and trace impedance calculators found on-line, they are not as thorough as specialized tools, and in simplifying the calculations, may omit critical variables. Silver Spring recommends the use of AppCAD Design Assistant. This software is available as a free download from Avago Technologies:

http://www.avagotech.com/appcad Additional support information on AppCAD can be found here:

http://www.hp.woodshot.com/

This reference design uses 1 oz copper. The base PCB material is ITEQ IT180A. Data sheet is available here:

http://www.prototron.com/documents/materials/IT180A.pdf which has an specified as 4.4. PCB Design Guidelines; Silver Spring Networks Milli 5 Development Board Layout Antenna trace design parameters PCB Stackup Coplanar Waveguide with Full Ground Pour Coplanar Waveguide with ground outline showing vias 50 mils spaced Transmission Line Measurements For design verification, use of an SParameter Network Analyzer, such as Agilent 8719S may be used to characterize the losses of the transmission line. Solder a calibrated coaxial cable to pin 16 (RF900, RF I/O port) pin on the PCB to make the following measurements. Path loss measurements, S12. Line input impedance (Smith chart format) once the line has been terminated with a 50 ohm load is shown below. FCC AND INDUSTRY CANADA GOVERNMENT GUIDELINES Silver Spring Networks Milli 5 FCC ID: OWSMIL51 IC: 5975A-MIL51 Modifications Changes or modifications not expressly approved by the party responsible for compliance could void the users authority to operate the equipment. Part 15 Certification Notice This device complies with Part 15 of the FCC Rules and Industry Canada licence-exempt RSS standard(s). Operation is subject to the following two conditions:

1. This device may not cause harmful interference, and 2. This device must accept any interference received, including interference that may cause undesired operation. The antenna of this transmitter must not be colocated or operating in conjunction with any other antenna or transmitter. The device should be installed so that people will not come within 20 cm (8 in.) of the antenna. Information to User for Class B digital device This equipment has been tested and found to comply with Part 15 of the FCC Rules. This equipment generates, uses, and can radiate radio frequency energy, and if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception (which can be determined by turning the equipment off and on), the user is encouraged to try to correct the interference by one or more of the following measures:

Reorient or relocate the receiving antenna. Increase the separation between the equipment and receiver. Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. Consult the dealer or an experienced radio/TV technician for help. Exigences dIndustrie Canada La carte dinterface rseau (NIC) Silver Spring Network Relay Point (NRP) DOIT tre installe par un technicien ayant reu une formation adquate. Une installation incorrecte peut annuler lautorisation de lutilisateur se servir de lquipement. Le prsent appareil est conforme aux CNR dIndustrie Canada applicables aux appareils radio exempts de licence. Lexploitation est autorise aux deux conditions suivantes:

(1) lappareil ne doit pas produire de brouillage, et.

(2) lutilisateur de lappareil doit accepter tout brouillage radiolectrique subi, mme si le brouillage est susceptible den compromettre le fonctionnement. Lantenne de cet metteur ne doit pas se trouver proximit de ou fonctionner en association avec une autre antenne ou un autre metteur. Lappareil doit tre install de telle sorte que les gens ne viendront pas au sein de 29 cm

(11.4 in.) de lantenne. Les changements ou modifications apports sans lapprobation expresse de lautorit responsable de la conformit pourront entraner lannulation de lautorisation dutilisation de cet quipement. Labeling Requirements for Host Device The following is an extract from FCC PART 15 UNLICENSED MODULAR TRANSMITTER APPROVAL, DA 001407, Released: June 26, 2000, Section 6 describing labeling requirements for devices containing a modular transmitter. Section 6. The modular transmitter must be labeled with its own FCC ID number, and, if the FCC ID is not visible when the module is installed inside another device, then the outside of the device into which the module is installed must also display a label referring to the enclosed module. This exterior label can use wording such as the following:

Contains Transmitter Module FCC ID: XYZMODEL1 or Contains FCC ID: XYZMODEL1. Any similar wording that expresses the same meaning may be used. The Grantee may either provide such a label, an example of which must be included in the application for equipment authorization, or, must provide adequate instructions along with the module which explain this requirement. In the latter case, a copy of these instructions must be included in the application for equipment authorization. The following is an extract from RSS-GEN, General Requirements and Information for the Certification of Radio Apparatus, Section 3.2.1, describing labeling requirements for a host device integrating a radio module. The host device shall be properly labelled to identify the modules within the host device. The Industry Canada certification label of a module shall be clearly visible at all times when installed in the host device, otherwise the host device must be labelled to display the Industry Canada certification number of the module, preceded by the words Contains transmitter module, or the word Contains, or similar wording expressing the same meaning, as follows:

Contains transmitter module IC: XXXXXXYYYYYYYYYYY where XXXXXXYYYYYYYYYYY is the modules certification number. Lextrait suivant provient du Cahier des charges sur les normes radiolectriques (CNR);

exigences gnrales et information relatives la certification des appareils radio, section 3.2.1, et dcrit les exigences en matire dtiquetage pour un dispositif hte intgrant un module radio. Le dispositif hte doit tre correctement tiquet afin didentifier les modules quil comprend. Ltiquette de certification Industrie Canada dun module doit toujours tre bien visible lors de linstallation sur un dispositif hte. Dans le cas contraire, le dispositif hte doit tre tiquet de faon afficher le numro de certification Industrie Canada du module, prcd de lexpression Contains transmitter module ou du mot Contains , ou dune formulation similaire ayant la mme signification. Par exemple :

Contains transmitter module IC : XXXXXXYYYYYYYYYYY o XXXXXXYYYYYYYYYYY reprsente le numro de certification du module. The applicant for equipment certification of the module shall provide with each unit of the module either a label such as described above, or an explanation and instructions to the user as to the host device labelling requirements. External Antenna Integration (RSS-GEN) This radio transmitter 5975A-MIL51 has been approved by Industry Canada to operate with the antenna types listed in Table 2 with the maximum permissible gain and required antenna impedance for each antenna type indicated. Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited for use with this device. Cet metteur radio 5975A-MIL51 a t approuv par Industrie Canada pour fonctionner avec les types dantenne numrs dans le tableau 2 ci-dessous avec le gain maximal admissible et limpdance dantenne requise pour chaque type dantenne indiqu. Les types dantennes ne figurant pas dans cette liste, ayant un gain suprieur au gain maximum. External Antenna Antenna Antenna Type 900 MHz Gain (dBi) JPole, SSN 201000006 Omni Directional Linx, ANT-916-CW-RH-

SMAND Pulse W1900 Stub Stub 3

-1.3 1 Antenna Impedance 50 50 50 Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that necessary for successful communication. Conformment la rglementation dIndustrie Canada, le prsent metteur radio peut fonctionner avec une antenne dun type et dun gain maximal (ou infrieur) approuv pour lmetteur par Industrie Canada. Dans le but de rduire les risques de brouillage radiolectrique lintention des autres utilisateurs, il faut choisir le type dantenne et son gain de sorte que la puissance isotrope rayonne quivalente (p.i.r.e.) ne dpasse pas lintensit ncessaire ltablissement dune communication satisfaisante. Milli 5 Radio Certifications Silver Spring Networks Milli 5 is integrated into application specific hosts which provide power regulation, buffered data inputs, and 50 ohm transmission line to antenna or external antenna connector. The following table describes the hosts that support Milli 5 FCC/IC Certification. SSN P/N 174-0768-00 Description Hardware Development Kit

(HDK) Antenna External SMA 170-0818-00 Logistics NIC (LNIC) On-board SSNI 420-0319-00 170-0845-00 Milli Arduino Shield Board External SMA OEM Certifications Silver Spring Networks Milli 5 is FCC/IC Certified as Limited Modular Approval (LMA). LMA may be granted to a device which cannot meet all the requirements of a Single Modular Transmitter and if compliance can be demonstrated under the operating conditions in which the device will be used. OEMs have the following options for FCC/IC Certification using an LMA:

Option 1: Use current FCC/IC Grant, without need of an additional Certification by following these rules:

Design to the strict guidelines for layout as described in 50 ohm PCB Design Guidelines, Use an external antenna of same type as tested (JPole OmniDirectional) with equal or less gain, Deliver power regulation to Milli 5 as described in Recommended Operating Conditions, Deliver buffered modulation/data inputs to Milli 5 Label the host device with, Contains FCC ID: OWSMIL51 and Contains IC:

5975A-MIL51. Option 2: If all rules from Option 1 are used, but a different type of antenna is required for the application, request a Change in ID application to reuse data from the current FCC/IC Grant, then apply for a Class 2 Permissive Change to add the antenna. The integration would require some additional conformity against CFR 47 Parts 15.203, 15.209, and RF exposure to add antenna to the Certification. Contact Silver Spring Networks for authorization to apply for a Class II Permissive Change. Option 3: Integration will need to pursue own full FCC Certification if design does not follow strict guidelines for layout. OEM may choose to obtain own FCC Certification even if guidelines are followed. Collocation: If other wireless technologies are operational at the same time, then certification testing may be required for each technology, including evaluations of simultaneous transmissions from independent transmitters. ABOUT SILVER SPRING NETWORKS Silver Spring Networks enables the Internet of Important Things by reliably and securely connecting things that matter. Cities, utilities, and companies on five continents use the companys costeffective, highperformance IoT network and data platform to operate more efficiently, get greener, and enable innovative services that can improve the lives of millions of people. With more than 25.5 million devices delivered, Silver Spring provides a proven standards-based platform safeguarded with military grade security. Silver Spring Networks customers include Baltimore Gas & Electric, CitiPower & Powercor, ComEd, Consolidated Edison, CPS Energy, Florida Power & Light, Pacific Gas & Electric, Pepco Holdings, and Singapore Power. Silver Spring has also deployed networks in Smart Cities including Copenhagen, Glasgow, Paris, Providence, and Stockholm. To learn more, visit www.ssni.com. Corporate Headquarters 230 W Tasman Drive San Jose, CA 95134 O +1 669 770 4000 Toll Free +1 866 204 0200 Copyright 2017 Silver Spring Networks. All Rights Reserved. Rev. 5/2/2017 All trademarks are the properties of their respective owners. Confidential Information of Silver Spring Networks, Inc., provided under nondisclosure obligations. www.ssni.com