Ingenu EM110100 Electric Meter Communications Module User Manual Model EM110100 Integration Specification

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Document Author:	On-Ramp Wireless Incorporated

Model EM110100
“Raptor”
Integration
Specification
On-Ramp Wireless Confidential and Proprietary. This document is not to be used, disclosed, or distributed to
anyone without express written consent from On-Ramp Wireless. The recipient of this document shall respect the
security of this document and maintain the confidentiality of the information it contains. The master copy of this
document is stored in electronic format, therefore any hard or soft copy used for distribution purposes must be
considered as uncontrolled. Reference should be made to On-Ramp Wireless to obtain the latest revision.
On-Ramp Wireless Incorporated
10920 Via Frontera, Suite 200
San Diego, CA 92127
U.S.A.
Copyright © 2012 On-Ramp Wireless Incorporated.
All Rights Reserved.
The information disclosed in this document is proprietary to On-Ramp Wireless Inc., and is not to be used
or disclosed to unauthorized persons without the written consent of On-Ramp Wireless. The recipient of
this document shall respect the security of this document and maintain the confidentiality of the
information it contains. The master copy of this document is stored in electronic format, therefore any
hard or soft copy used for distribution purposes must be considered as uncontrolled. Reference should
be made to On-Ramp Wireless to obtain the latest version. By accepting this material the recipient agrees
that this material and the information contained therein is to be held in confidence and in trust and will not
be used, copied, reproduced in whole or in part, nor its contents revealed in any manner to others without
the express written permission of On-Ramp Wireless Incorporated.
On-Ramp Wireless Incorporated reserves the right to make changes to the product(s) or information
contained herein without notice. No liability is assumed for any damages arising directly or indirectly by
their use or application. The information provided in this document is provided on an “as is” basis.
This document contains On-Ramp Wireless proprietary information and must be shredded when
discarded.
This documentation and the software described in it are copyrighted with all rights reserved. This
documentation and the software may not be copied, except as otherwise provided in your software
license or as expressly permitted in writing by On-Ramp Wireless, Incorporated.
Any sample code herein is provided for your convenience and has not been tested or designed to work
on any particular system configuration. It is provided “AS IS” and your use of this sample code, whether
as provided or with any modification, is at your own risk. On-Ramp Wireless undertakes no liability or
responsibility with respect to the sample code, and disclaims all warranties, express and implied,
including without limitation warranties on merchantability, fitness for a specified purpose, and
infringement. On-Ramp Wireless reserves all rights in the sample code, and permits use of this sample
code only for educational and reference purposes.
This technology and technical data may be subject to U.S. and international export, re-export or transfer
(“export”) laws. Diversion contrary to U.S. and international law is strictly prohibited.
Ultra-Link Processing™ and Random Phase Multiple Access™ are trademarks of On-Ramp Wireless.
Other product and brand names may be trademarks or registered trademarks of their respective owners.
Model EM110100 Integration Specification
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September 13, 2012
Contents
1 Overview ................................................................................................................ 1
1.1 ULP Wireless Network ............................................................................................................... 1
1.2 Referenced Documents ............................................................................................................. 2
2 Safety and Regulatory Considerations ............................................................... 3
2.1 Danger: High Voltages ............................................................................................................... 3
2.2 FCC Warnings ............................................................................................................................ 3
2.3 IC Warnings ............................................................................................................................... 4
2.4 TELEC Warnings ....................................................................................................................... 5
2.5 Usage ......................................................................................................................................... 5
2.5.1 Note to Integrators ............................................................................................................ 5
2.5.2 RF Exposure Statement ................................................................................................... 5
2.6 Antennas .................................................................................................................................... 5
2.7 Block Diagram ............................................................................................................................ 6
2.8 EMC Certifications ..................................................................................................................... 6
2.9 WEEE Directive.......................................................................................................................... 7
2.10 REACH Directive...................................................................................................................... 7
2.11 RoHS Directive......................................................................................................................... 7
3 DC and RF Characteristics ................................................................................... 8
3.1 Absolute Maximum Ratings ....................................................................................................... 8
3.2 Recommended Operating Conditions ........................................................................................ 8
3.3 Operating Characteristics .......................................................................................................... 8
3.4 Power Supplies .......................................................................................................................... 9
4 Electrical Interface .............................................................................................. 10
4.1 Signal Connectors .................................................................................................................... 10
4.2 Pin and Signal Descriptions ..................................................................................................... 11
4.3 Environmental .......................................................................................................................... 11
4.3.1 ESD ................................................................................................................................ 11
4.3.2 Harsh Environments ....................................................................................................... 11
5 Mechanical Information ...................................................................................... 12
5.1 Mechanical Drawing ................................................................................................................. 12
6 Installation and Assembly Drawings................................................................. 13
6.1 EM110100 Raptor Schematics ................................................................................................ 13
6.2 Installation and Assembly ........................................................................................................ 13
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6.2.1 Assembly Torque Values................................................................................................ 14
6.3 Product Labels ......................................................................................................................... 14
7 Provisioning ........................................................................................................ 16
7.1 Manual ..................................................................................................................................... 16
7.2 Automatic ................................................................................................................................. 16
Appendix A Provisioning Process and Work Flow ............................................. 17
Appendix B Test Mode .......................................................................................... 28
Appendix C REACH Compliance Statements ...................................................... 32
Appendix D Abbreviations and Terms ................................................................. 34
Appendix E Raptor Mechanical Drawing and Schematics ................................. 36
Figures
Figure 1. On-Ramp Wireless ULP Network ..................................................................................... 1
Figure 2. Meter Test Connection Diagram ....................................................................................... 3
Figure 3. Raptor Block Diagram ....................................................................................................... 6
Figure 4. MCM110 Circuit Card ..................................................................................................... 10
Figure 5. Raptor Mechanical Drawing............................................................................................ 12
Figure 6. Meter Assembly with Raptor MCM ................................................................................. 13
Figure 7. Detail, Raptor Board Mounting ....................................................................................... 14
Figure 8. EM110100 Product Label ............................................................................................... 15
Figure 9. Carton Label ................................................................................................................... 15
Figure 10. Raptor Mechanical Dimensions .................................................................................... 36
Tables
Table 1. On-Ramp Wireless EMC Certified Antenna ....................................................................... 5
Table 2. Raptor EMC Compliance List............................................................................................. 6
Table 3. Absolute Maximum Ratings ............................................................................................... 8
Table 4. Operating Conditions ......................................................................................................... 8
Table 5. Operating Characteristics .................................................................................................. 8
Table 6. ESD Rating ...................................................................................................................... 11
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Revision History
Revision
Release Date
Change Description
September 13, 2012
Initial release
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1 Overview
The purpose of this document is to provide guidelines allowing an integrator to design a host
product that uses the “Raptor” MCM (Meter Communications Module) and ensures that the
system meets all of its technical objectives and requirements.
1.1 ULP Wireless Network
The On-Ramp Wireless ULP network is comprised of Nodes (such as Raptor) and Access Points
(AP) and operates in the unlicensed 2.4 ISM band. The Raptor circuit card is designed to easily
integrate into electric meters, through standard interfaces, enabling robust wireless
communication with one or more Access Points interfaced with a service provider’s local or wide
area network.
Figure 1. On-Ramp Wireless ULP Network
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1.2 Referenced Documents
The following documents are referenced and provide more detail:

ULP Node Interface Library (UNIL) (010-0066-00)
Provides information about the library of portable C code provided by On-Ramp Wireless
which can be integrated into a customer’s existing software architecture.

UNIL API (010-0072-00)
Provides details relating to the UNIL Application Programming Interface.

Test Mode Interface (in Appendix A)
Provides details relating to the Test Mode Interface.

ULP Node Host Message Specification (014-0020-00)
Provides details relating to Node Host commands and messages.

Raptor FCC/IC/TELEC EMC Compliance Grants (TBD, not yet issued)
These are the Regulatory Grants issued by their respective governments.

NPT User Guide (010-0060-00)
Describes setup, configuration, and use of a collection of utilities called Node Provisioning
Tools (NPT) used for Node provisioning.
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2 Safety and Regulatory Considerations
2.1 Danger: High Voltages
When the Raptor is integrated to the meter, high voltages are present:
CAUTION: When the Raptor is mounted in an I210 Meter, the term “GND” or “Ground” does
NOT refer to Earth ground. All signals will have a 120/240VAC power superimposed onto
those lines. All signals to/from the raptor need to be isolated. No grounded instruments, or
computers, should touch the Raptor signals.
It is recommended to use the following isolation/drivers.
Isolator:
http://www.bb-elec.com/product_family.asp?FamilyId=651&webSyncID=85656815-ad8a-a188b050-1143ad0dee45&sessionGUID=bc450985-a6c1-9981-a0d7-6391dcb1c046
UART:
http://www.digikey.com/product-detail/en/TTL-232R-3V3-WE/768-1016-ND/1836394
Figure 2. Meter Test Connection Diagram
2.2 FCC Warnings
This device complies with part 15 of the Federal Communications Commission (FCC) Rules.
Operation is subject to the following two conditions:
1. This device may not cause harmful interference.
2. This device must accept any interference received, including interference that may cause
undesired operation.
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Changes or modifications not expressly approved by the manufacturer could void the user’s
authority to operate the equipment.
NOTE:
This equipment has been tested and found to comply with the limits for a Class B
digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to
provide reasonable protection against harmful interference in a residential
installation.
WARNING: This equipment generates, uses, and can radiate radio frequency energy. If not
installed and used in accordance with the instructions, this equipment 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:

Re-orient 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.
2.3 IC Warnings
The installer of this radio equipment must ensure that the antenna is located or pointed so that
it does not emit RF field in excess of Health Canada limits for the general population. Consult
Safety Code 6 which is obtainable from Health Canada’s website http://www.hc-sc.gc.ca/indexeng.php.
Operation is subject to the following two conditions:
1. This device may not cause harmful interference.
2. This device must accept any interference received, including interference that may cause
undesired operation.
To reduce potential radio interference to other users, select the antenna type and its gain so
that the equivalent isotropically radiated power (EIRP) is not more than that permitted for
successful communication.
Canadian Two Part Warning Statement:
This device complies with Industry Canada licence-exempt RSS standard(s). Operation is subject
to the following two conditions: (1) this device may not cause interference, and (2) this device
must accept any interference, including interference that may cause undesired operation of the
device.
Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio
exempts de licence. L'exploitation est autorisée aux deux conditions suivantes : (1) l'appareil ne
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doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit accepter tout brouillage
radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement.
2.4 TELEC Warnings
None known.
2.5 Usage
FCC ID: XTE-EM110100. IC: 8655A-EM110100. This device is only authorized for use in fixed and
mobile applications. To meet FCC and other national radio frequency (RF) exposure
requirements, the antenna for this device must be installed to ensure a separation distance of at
least 20cm (8 inches) from the antenna to a person.
2.5.1 Note to Integrators
A label showing the FCC ID and IC designators, listed above, must be affixed to the exterior of
any device containing the Raptor (if the Raptor is not visible). The exterior label must include:
Contains FCC ID: XTE-EM110100, IC: 8655A-EM110100, TELEC: TBD, not yet issued.
2.5.2 RF Exposure Statement
The air interface supports operation on channels in the 2402 MHz – 2476 MHz range for FCC/IC
regulatory domains and 2402 MHz – 2482 MHz for the TELEC regulatory domain.
Before this product becomes operational it must undergo a commissioning procedure, during
which critical information required for operation is entered into the device and stored in nonvolatile storage. It is during the initial commissioning procedure that the regulatory domain,
under which the device will operate, is set. Subsequent configuration of the device during
operation is checked against the commissioned regulatory domain and non-permitted channels
or transmit power levels are rejected and the device will not transmit until a permissible
configuration per the commissioned regulatory domain is set.
2.6 Antennas
This device has been certified to operate with the built-in (PCB chip) antenna listed below. To
adhere to these EMC certifications requires that only this antenna be used. All other antennas
are strictly prohibited for use with the Raptor unless new EMC certifications are obtained. The
antenna impedance is 50 ohms.
Table 1. On-Ramp Wireless EMC Certified Antenna
Manufacturer
Part Number
Gain
Type
Ethertronics
1001013
2 dBi
Monopole
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2.7 Block Diagram
Some regulatory domains require a block diagram of the module for their documentation similar
to that shown in the following figure.
Figure 3. Raptor Block Diagram
2.8 EMC Certifications
The Raptor is designed to meet regulations for world-wide use. It has EMC modular approval
certifications in the United States, Canada, and Japan. This allows the Raptor to be installed in
any final product and only Unintentional Radiator testing is required of the final product. This
saves much cost and time for System Integrators. The certifications currently achieved are listed
in the following table. Other countries will vary.
Table 2. Raptor EMC Compliance List
Country
Certifying Agency
United States
Federal
Communications
Commission (FCC)
Canada
Industry Canada (IC)
Japan
TELEC
Requirement Documents or Paragraph





15.207 for powerline conducted emissions.
15.215 for TX 20dB bandwidth
15.247 for RF TX 6dB bandwidth, power,
conducted and radiated emissions.
RSS210e includes FCC tests and IC-specific
tests (RX radiated emissions, 99% BW).
ARIB STD-T66 for frequency error, bandwidth,
process gain, spurious emissions, antenna
power, and EiRP.
Note: ARIB STD-T66 is sometimes also referred to as Japanese Radio Law; Article 2, Item 19,
Paragraph 1, Category WW with DSSS modulation.
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Safety and Regulatory Considerations
The Grants issued by their respective governments for Raptor are available to System
Integrators to ensure that the product has been certified. For more information about these
documents, see the list of documents referenced in section 1.
2.9 WEEE Directive
Neither the Raptor nor node are considered “end products” that put them under the WEEE
initiatives in the EU. The WEEE directives do not apply to the Raptor product.
2.10 REACH Directive
As of August 2012 the Raptor by itself is REACH compliant under 1907/2006/EC. On Ramp
Wireless expects to receive a declaration of conformance from the Taiwan-based manufacturer
of the node starting in September 2012. REACH compliance statements are found in Appendix C.
2.11 RoHS Directive
The Raptor and node comply with RoHS directive 2002/95/EC. On Ramp Wireless has received
Certificates of Conformance (CoC) for all components, printed circuit board and contract
manufacturers for the Raptor and uNode. Copies of the CoCs are stored at On Ramp Wireless
and available upon request.
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3 DC and RF Characteristics
3.1 Absolute Maximum Ratings
Operation outside of the Absolute Maximum Ratings may damage the unit.
Table 3. Absolute Maximum Ratings
Parameter
Min
Max
Unit
Storage Temperature (Ts)
-40
85
⁰C
Ambient Temperature (Ta)
-40
85
⁰C
Input Voltage (VBATT)
0.0
5.0
3.2 Recommended Operating Conditions
Operation outside of the Recommended Operating Conditions may not yield proper operation.
Table 4. Operating Conditions
Parameter
Min
Max
Unit
Ambient Temperature (Ta)
-40
85
⁰C
Input voltage (VBATT)
3.0
4.4
3.3 Operating Characteristics
The following characteristics apply across the -40°C to +85°C temperature range unless
otherwise noted.
Table 5. Operating Characteristics
Parameter
ORW Raptor Module
Wireless Frequency
2.4 GHz ISM
Bandwidth
1 MHz nominal
Modulation
Dynamic-Direct Sequence Spread Spectrum (D-DSSS)
Multiple Access Scheme
Random Phase Multiple Access (RPMA)
Transmit Power (peak EiRP)
+23 dBm (FCC/IC)
+12 dBm (TELEC)
Receive Sensitivity
-136 dBm (includes peak antenna gain)
Antenna
Integrated antenna diversity
Data Throughput
60 kbps (at access point in 1 MHz channel bandwidth)
Outdoor Range (FCC/IC
markets)
Pole Top:
4 – 6 square miles
Building Top:
70 – 400 square miles
Communication Tower: 140 – 420 square miles
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DC and RF Characteristics
Maximum Allowable Path Loss
172 dB (FCC/IC)
152 dB (TELEC)
Current Consumption
0.22A max. @ 4VDC (during TX1)
0.20A max. @ 4VDC (during RX2)
Operating Temperature
-40°C to 85°C
Relative Humidity
5% to 95% non-condensing
Security
AES 128-bit payload encryption, mutual authentication of network
elements
Certifications
Raptor FCC, IC, and TELEC EMC certifications pending.
Meter ANSI and Unintentional Radiator certifications required
once integrated into the meter product.
Note: Specifications subject to change
Note 1: During TX mode the supercap charger is disabled to reduce peak currents.
Note 2: During RX mode the supercap charger is enabled. The supercap charge current is limited
to about 110mA.
3.4 Power Supplies
The Raptor utilizes two main power supplies when it is functioning:
1. Main switching power supply (3.3VDC output).
This main buck-boost power supply is operating at all times. It supplies power to all digital
and radio circuits.
2. Supercap Charger (~4.4VDC output).
This boost type switching power supply is used to charge the super capacitors. It can only
operate with an input supply up to about 4.4VDC. It is in use at all times when primary
power is applied. Once primary power is interrupted this power supply is disabled and the
super caps supply power to the main switching power supply.
Additionally the ULP uNode module on the Raptor PCB has its own switching power supply
(buck-boost) that uses the Raptor’s main switching power supply as its source.
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4 Electrical Interface
This chapter describes the electrical interface of the MCM110.
4.1 Signal Connectors
An image of both sides of the MCM110 PCB (circuit card) is shown below.
Figure 4. MCM110 Circuit Card
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Electrical Interface
4.2 Pin and Signal Descriptions
The following table lists the pins and signals for the J500 connector.
MCM Pin #
Pin Name
Signal Description
SPARE 1
GPIO to/from AMI, Not Used.
SPARE 2
GPIO to/from AMI, Not Used.
M_COMM_BD_FORCE
AMI input; 2 functions, Board Detect and Meter in optical
communication session.
METER_VDD
AMI power input; 4.0VDC nominal.
M_PWR_FAIL
AMI input; Power Good = HIGH, Power Off = LOW.
GROUND
Electrical Ground.
M_RXD_FROM_AMR
AMI output to UART. 9600 bps, 8-bit, no parity, 1 stop bit.
M_COMM_BD_SENSE
AMI output for AMR detection initial handshaking.
M_TXD_TO_AMR
AMI input to UART. 9600 bps, 8-bit, no parity, 1 stop bit.
10
M_TROUBLE
AMI input for meter trouble notification.
11
M_LINE_ZC
AMI Input, AC line zero crossing signal.
12
M_MUX_CTRL
AMI output, set low to communicate with meter.
4.3 Environmental
4.3.1 ESD
The Raptor has bidirectional ESD protection diodes on its 8 digital I/O pins providing protection
to IEC 61000-4-2; level 4.
Table 6. ESD Rating
ESD Model
Class and Minimum Voltage
HBM
Class 1C ( >1000V)
MM
Class A (>100V)
The antennas have protection in the form of an inductor to ground, thus allowing some
robustness to direct ESD strikes. Additionally, the antennas are encapsulated in the
polycarbonate housing of the meter – so there is little chance of high voltages on the antennas,
or others of the board.
4.3.2 Harsh Environments
The Raptor is designed to be an embedded circuit card in an enclosed protective shell. It is not
designed to be exposed to outdoor environments without a case or similar protections. An IP 67
or better protective casing is strongly recommended. The polycarbonate dome of the meter
nominally provides robustness to harsh environments.
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5 Mechanical Information
5.1 Mechanical Drawing
A complete mechanical drawing of the EM110100 board is in Appendix C of this document.
All units in millimeters.
Figure 5. Raptor Mechanical Drawing
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6 Installation and Assembly Drawings
6.1 EM110100 Raptor Schematics
Raptor board schematics are found in Appendix C of this document.
6.2 Installation and Assembly
Figures 6 and 7 show how Raptor is mounted inside the GE meter.
Figure 6. Meter Assembly with Raptor MCM
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Figure 7. Detail, Raptor Board Mounting
6.2.1 Assembly Torque Values
Two screws (P/N 9925887027, #4-24X.31 self-tapping, type BF Phillips pan-head steel zinc
screw) are required to mount Raptor in place. The screws have the following recommended
torque values: 6 to 7 in.-lbf.
6.3 Product Labels
The product label is shown in Figure 8.
NOTE: The TELEC ID number shown is NOT our number for this product. It is shown for
placement only.
An example of the carton label is shown in Figure 9.
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Figure 8. EM110100 Product Label
Figure 9. Carton Label
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7 Provisioning
The tools and software required for provisioning the Raptor modules are described in this
section.
The Provisioning process can be handled in two main ways:

Manual for small runs

Automatic for full production.
7.1 Manual
The Node Provisioning Tool (see referenced tools/documents) can be used to provision Raptors
in small quantity. The PC will attach to the DUT Raptor via its Provisioning header (UART is 3.3V).
The Raptor connector is J202 and requires a “TE Connectivity” connector PN 1470364-3 to mate
with it. The pinout is:

Pin 1 Debug_RX (3V3 logic)

Pin 2 Debug_TX (3V3 logic)

Pin 3 GND
CAUTION: When the Raptor is mounted in an I210 Meter, the term “GND” or “Ground” does
NOT refer to Earth ground. All signals will have a 120/240VAC power imposed onto
those lines. All signals to/from the Raptor board need to be isolated. No grounded
instruments, or computers, should touch the Raptor board signals.
Use the setup as described in Figure 2.
7.2 Automatic
The automatic process is defined and built by the Customer. On-Ramp Wireless has assisted in
development of these tools but are not a property of On-Ramp Wireless. It is the customer that
owns, defines, develops, documents and maintains the Manufacturing Tools.
The Provisioning process nominally deals with:

Loading in current versions of Software to microNode and K20 processors

Configuring (channels, TX power, etc)

Setting and configuring Security Keys (via LKS server)

Performing an OTA test to ensure the complete meter-Raptor-antenna chain is verified

Lock down all access ports such as UART header and JTAG.
A graphical representation of the provisioning process is shown in Appendix A.
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Appendix A Provisioning Process and Work Flow
The following illustrations show a graphical representation of the provisioning process.
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Appendix B Test Mode
The test modes, described below, are set by setting the "testMode" parameter in the EMCM's
config file.
Normal Operating Mode 0
This mode is entered based on a flash configuration setting. This mode is persistent across
boots. This is the normal operating mode of the EMCM. UNIL is initialized to communicate with
the node. The meter software layer is initialized to communicate with the meter. Although the
EMCM is in its normal operating mode, as determined by the flash config setting, other factors
may subsequently cause the EMCM to change to a non-normal operating mode (e.g. meter is
not in metering mode).
Non-Persistent Idle / Factory Test Mode 1
This mode is entered based on the testMode flash configuration setting. This mode is not
persistent across boots (self clearing). UNIL is initialized to pass-through mode. Meter software
layer is not initialized. The UART on the AMR (automatic meter reading) serial interface is placed
in loopback mode (using the same baud rate as the meter, e.g. 9600). Same as mode 2 except
the flash testMode setting is automatically cleared to mode 0 when entering this mode. A
subsequent "set test mode" command can set the cleared value to some other test mode value.
Persistent Idle / Factory Test Mode 2
This mode is entered based on the testMode flash configuration setting. This mode is persistent
across boots. UNIL is initialized to pass-through mode. Meter software layer is not initialized.
The UART on the AMR serial interface is placed into loopback mode (using the same baud rate
as the meter, e.g. 9600). Same as mode 1 except the flash testMode setting is persistent across
boots. To exit this mode, the test mode configuration setting must be set to another value which
will take effect on eMCM reset.
Non-Persistent Node RF Test Mode 3
This mode is entered based on the testMode flash configuration setting. This mode is not
persistent across boots (self clearing). UNIL is initialized to pass-through mode. The meter
software layer is not initialized. Same as mode 4 except the flash testMode setting is
automatically cleared to mode 0 when entering this mode. A subsequent "set test mode"
command can set the cleared value to some other test mode value.


The TX test mode is controlled by the "txTestMode" parameter in the config file.

1 = CW_CENTER

2 = CW_OFFSET

3 = MODULATED
The antenna is controlled by the "txTestAntenna" parameter in the config file.

0 or 1.
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

The frequency is controlled by the "txTestCenterFreqKhzOffset" parameter in the config file.

KHz offset from 2.4 GHz

2000 - 100000

e.g., 50000 = 2.45 GHz
The VGA is controlled by the "txTestVga" parameter in the config file.


Test Mode
0 - 63, 255
The on/off duration is controlled by the "txTestModeSec" and "txTestModeUsec"
parameters in the config file.
Persistent Node RF Test Mode 4
This mode is entered based on the testMode flash configuration setting. This mode is persistent
across boots. UNIL is initialized to pass-through mode. The meter software layer is not
initialized. Same as mode 3 except the flash testMode setting is persistent across boots. To exit
this mode, the test mode configuration setting must be set to another value which will take
effect on eMCM reset.
Non-Persistent Manufacturing Cal Mode 5
This mode is entered based on the testMode flash configuration setting. This mode is not
persistent across boots (self clearing). UNIL is initialized normally so that it communicates with
the node. The meter software layer is not initialized. The UART on the AMR serial interface is not
initialized or used. Same as mode 6 except the flash testMode setting is automatically cleared to
mode 0 when entering this mode. A subsequent "set test mode" command can set the cleared
value to some other test mode value.
Persistent Manufacturing Cal Mode 6
This mode is entered based on the testMode flash configuration setting. This mode is persistent
across boots. UNIL is initialized normally so that it communicates with the node. The meter
software layer is not initialized. The UART on the AMR serial interface is not initialized or used.
Same as mode 5 except the flash testMode setting is persistent across boots. To exit this mode,
the test mode configuration setting must be set to another value which will take effect on
eMCM reset.
Non-Persistent Meter Diagnostic Mode (Not Yet Implemented)
This mode is entered based on a flash configuration setting. This mode is not persistent across
boots (self clearing). UNIL is initialized normally so that it communicates with the node. The
meter software layer is initialized and communication to the meter is tested and validated. If
communication with either the node or the meter fails (or any other error condition detected),
then the red LED is blinked with an error code indefinitely (or until the deployment mode LED
timer expires). If no errors are detected, the green LED is blinked normally to indicate network
connection state (scanning, joined, etc). A reset is required to recover. Note: this mode may not
be needed if a basic diagnostic or POST check is done by the EMCM as part of its initialization
process.
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Test Mode
Setting EMCM to Test Mode 1 - Non-Persistent Idle Factory Test Mode
How to Enter

Set the 'testMode' flag in the config file to one.
e.g.

./emcm_set_cfg.py -d /dev/ttyS0 --testMode=1
Reset the EMCM to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
How to Exit

Because this mode is non-persistent, it can be exited via an EMCM reset.

Reset the EMCM to exit the test mode. By default, the EMCM will return to normal
operational mode 0 after reset unless another mode was explicitly specified with the
emcm_set_cfg.py command prior to resetting.
e.g.

./emcm_dev_reset.py -d /dev/ttyS0 --emcm
If a different mode is desired upon reset, explicitly
Description

UNIL is in pass-through mode.

Meter UART is in loopback mode.

AHP debug port is functional.

Mode is not persistent after resets.
Setting EMCM to Test Mode 2 - Persistent Idle Factory Test Mode
How to Enter
 Set the 'testMode' flag in the config file to two.
e.g.
./emcm_set_cfg.py -d /dev/ttyS0 --testMode=2
 Reset the EMCM to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
How to Exit
 Because this mode is persistent, it will remain in effect across EMCM resets.
 Set the 'testMode' flag to the new desired mode, e.g. normal operational mode 0.
e.g.
./emcm_set_cfg.py -d /dev/ttyS0 --testMode=0
 Reset the EMCM for the new mode to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
Description
 UNIL is in pass-through mode.
 Meter UART is in loopback mode.
 AHP debug port is functional.
 Mode is persistent across resets.
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Test Mode
Setting EMCM to Test Mode 3 - Non-Persistent RF Test Mode
How to Enter
 Set the 'testMode' flag in the config file to three.
e.g.
./emcm_set_cfg.py -d /dev/ttyS0 --testMode=3
 Reset the EMCM to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
How to Exit
 Because this mode is non-persistent, it can be exited via an EMCM reset.
 Reset the EMCM to exit the test mode. By default, the EMCM will return to normal
operational mode 0 after reset unless another mode was explicitly specified with the
emcm_set_cfg.py command prior to resetting.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
 If a different mode is desired upon reset, explicitly
Description
 UNIL is partially operational.
 Meter UART is disabled.
 AHP debug port is functional.
 Mode is not persistent after resets.
Setting EMCM to Test Mode 4 - Persistent RF Test Mode
How to Enter
 Set the 'testMode' flag in the config file to four.
e.g.
./emcm_set_cfg.py -d /dev/ttyS0 --testMode=4
 Reset the EMCM to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
How to Exit
 Because this mode is persistent, it will remain in effect across EMCM resets.
 Set the 'testMode' flag to the new desired mode, e.g. normal operational mode 0.
e.g.
./emcm_set_cfg.py -d /dev/ttyS0 --testMode=0
 Reset the EMCM for the new mode to take effect.
e.g.
./emcm_dev_reset.py -d /dev/ttyS0 --emcm
Description
 UNIL is partially operational.
 Meter UART is disabled.
 AHP debug port is functional.
Mode is persistent across resets.
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Appendix C REACH Compliance Statements
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Appendix D Abbreviations and Terms
Abbreviation/Term
Definition
AGC
Automatic Gain Control
ALC
Automatic Level Control
AMI
Advanced Metering Infrastructure
AMR
Automatic Meter Reading
AP
Access Point (this product)
API
Application Programming Interface
ASIC
Application-Specific Integrated Circuit
BOM
Bill of Materials
BW
Bandwidth
CMOS
Complementary Metal-Oxide-Semiconductor
CPOL
Clock Polarity (for SPI)
CPU
Central Processing Unit
DFS
Dynamic Frequency Selection
DPLL
Digital Phase-Locked Loop
EMC
Electromagnetic Compatibility
ESD
Electrostatic Discharge
ETSI
European Telecommunications Standards Institute
EVM
Error Vector Magnitude
FCC
Federal Communications Commission
FER
Frame Error Rate
GND
Ground
GPIO
General Purpose Input/Output
HBM
Human Body Model
IC
Industry Canada
IIP3
Input Third-Order Intercept Point
LDO
Low Drop Out
LNA
Low Noise Amplifier
LO
Local Oscillator
microNode
Second generation of the ULP wireless module that communicates sensor
data to an Access Point. The microNode forms the basis for ULP
communications of the Raptor product.
MISO
Master Input, Slave Output
MM
Machine Model
MOSI
Master Output, Slave Input
MRQ
Master Request
MSL
Moisture Sensitivity Level
Node
The generic term used interchangeably with eNode, microNode, or dNode.
NPT
Node Provisioning Tools
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Abbreviations and Terms
Abbreviation/Term
Definition
OTA
Over-the-Air
PA
Power Amplifier
PAPR
Peak-to-Average Power Ratio
PCB
Printed Circuit Board
POR
Power On Reset
QoS
Quality of Service
Raptor
On-Ramp Wireless AMI circuit card (PCB)
RF
Radio Frequency
RFIC
Radio Frequency Integrated Circuit
RoHS
Restriction of Hazardous Substances
RSSI
Receive Signal Strength Indicator
RT
Remote Terminal
RTC
Real Time Clock
RX
Receive/Receiver
SCLK
Serial Clock
SMT
Surface Mount Technology
SNR
Signal-to-Noise Ratio
SPI
Synchronous Peripheral Interface
SRDY
Slave Ready
SRQ
Slave Request
TX
Transmit/Transmitter
UART
Universal Asynchronous Receiver/Transmitter
ULP
Ultra-Link Processing™. On-Ramp Wireless proprietary wireless
communication technology.
UNIL
ULP Node Interface Library
VCO
Voltage Controlled Oscillator
VCTCXO
Voltage Controlled Temperature Compensated Crystal Oscillator
VSWR
Voltage Standing Wave Ratio
XO
Crystal Oscillator
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Appendix E Raptor Mechanical Drawing and Schematics
Figure 10. Raptor Mechanical Dimensions
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Model EM110100 Integration Specification
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---

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Title                           : Model EM110100 Integration Specification
Description                     : 014-0026-00 Rev. A
Creator                         : On-Ramp Wireless Incorporated
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Company                         : On-Ramp Wireless Incorporated
Headline                        : 014-0026-00 Rev. A
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