APEX CS5490-ISZ Two channel energy measurement ic Datasheet

CS5490
Two Channel Energy Measurement IC
Features & Description
Description
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The CS5490 is a high-accuracy, two-channel, energy measurement analog front end.
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Superior Analog Performance with Ultra-low Noise Level &
High SNR
Energy Measurement Accuracy of 0.1% over a 4000:1
Dynamic Range
Two Independent 24-bit, 4th-order, Delta-Sigma
Modulators for Voltage and Current Measurements
Configurable Digital Output for Energy Pulses, Interrupt,
zero-crossing, and Energy Direction
Supports Shunt Resistor, CT, and Rogowski Coil Current
Sensors
On-chip Measurements/Calculations:
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The CS5490 incorporates independent 4th order Delta-Sigma analog-to-digital converters for both channels, reference circuitry,
and the proven EXL signal processing core to provide active, reactive, and apparent energy measurement. In addition, RMS and
power factor calculations are available. Calculations are output
via a configurable energy pulse, or direct UART serial access to
on-chip registers. Instantaneous current, voltage, and power
measurements are also available over the serial port. The
two-wire UART minimizes the cost of isolation where required.
Active, Reactive, and Apparent Power
RMS Voltage and Current
Power Factor and Line Frequency
Instantaneous Voltage, Current, and Power
A configurable digital output provides energy pulses, zero-crossing, energy direction, or interrupt functions. Interrupts can be
generated for a variety of conditions including voltage sag or
swell, overcurrent, and more. On-chip register integrity is assured
via checksum and write protection. The CS5490 is designed to interface to a variety of voltage and current sensors, including shunt
resistors, current transformers, and Rogowski coils.
Overcurrent, Voltage Sag, and Voltage Swell Detection
Ultra-fast On-chip Digital Calibration
Configurable No-load Threshold for Anti-creep
Internal Register Protection via Checksum and Write
Protection
UART Serial Interface
On-chip Temperature Sensor
On-chip Voltage Reference (25ppm/°C Typ.)
Single 3.3 V Power Supply
Ultra-fine Phase Compensation
Low Power Consumption: <13 mW
Power Supply Configurations:
On-chip functionality makes digital calibration simple and ultra
fast to minimize the time required at the end of the customer production line. Performance across temperature is ensured with an
on-chip voltage reference with low drift. A single 3.3V power supply is required, and power consumption is low at <13mW. To
minimize space requirements, the CS5490 is offered in a low-cost
16-pin SOIC package.
ORDERING INFORMATION
- GNDA = 0 V, VDDA: +3.3 V
•
See Page 56.
Low-cost 16-pin SOIC Package
VDDA
VDDD
RESET
CS5490
IIN+
IIN-
PGA
4th Order 
Modulator
Digital
Filter
HPF
Option
UART
Serial
Interface
VIN+
VIN-
VREF+
VREF-
10x
Voltage
Reference
4th Order 
Modulator
Cirrus Logic, Inc.
http://www.cirrus.com
HPF
Option
TX
Calculation
Configurable
Digital
Output
Temperature
Sensor
System
Clock
GNDA
Digital
Filter
RX
DO
Clock
Generator
XIN
XOUT
Copyright  Cirrus Logic, Inc. 2012
(All Rights Reserved)
MODE
JUN’12
DS982F2
CS5490
TABLE OF CONTENTS
1. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
2. Pin Description
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
2.1 Analog Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
2.1.1 Voltage Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
2.1.2 Current Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
2.1.3 Voltage Reference . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.1.4 Crystal Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2 Digital Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2.1 Reset Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2.2 Digital Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2.3 UART Serial Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2.3.1 UART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
2.2.4 MODE Pin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
3. Characteristics & Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
4. Signal Flow Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4.1 Analog-to-Digital Converters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4.2 Decimation Filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4.3 IIR Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4.4 Phase Compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
4.5 DC Offset & Gain Correction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
4.6 High-pass & Phase Matching Filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
4.7 Digital Integrators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
4.8 Low-rate Calculations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
4.8.1 Fixed Number of Samples Averaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
4.8.2 Line-cycle Synchronized Averaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
4.8.3 RMS Current & Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
4.8.4 Active Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
4.8.5 Reactive Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
4.8.6 Apparent Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
4.8.7 Peak Voltage & Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
4.8.8 Power Factor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
4.9 Average Active Power Offset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
4.10 Average Reactive Power Offset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
5. Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5.1 Power-on Reset (POR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5.2 Power Saving Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5.3 Zero-crossing Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5.4 Line Frequency Measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
5.5 Energy Pulse Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
5.5.1 Pulse Rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
5.5.2 Pulse Width . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
5.6 Voltage Sag, Voltage Swell, and Overcurrent Detection . . . . . . . . . . . . . . . . . . . . .21
5.7 Phase Sequence Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
5.8 Temperature Measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
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CS5490
5.9 Anti-creep . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
5.10 Register Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
5.10.1 Write Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
5.10.2 Register Checksum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
6. Host Commands and Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1 Host Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.1 Memory Access Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.1.1 Page Select . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.1.2 Register Read . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.1.3 Register Write . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.2 Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
6.1.3 Checksum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
6.1.4 Serial Time Out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
6.2 Hardware Registers Summary (Page 0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
6.3 Software Registers Summary (Page 16) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
6.4 Software Registers Summary (Page 17) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
6.5 Software Registers Summary (Page 18) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
6.6 Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
7. System Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
7.1 Calibration in General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
7.1.1 Offset Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
7.1.1.1 DC Offset Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
7.1.1.2 AC Offset Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
7.1.2 Gain Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
7.1.3 Calibration Order . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
7.2 Phase Compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
7.3 Temperature Sensor Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
7.3.1 Temperature Offset and Gain Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
8. Basic Application Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
9. Package Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
10. Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
11. Environmental, Manufacturing, & Handling Information . . . . . . . . . . . . . . . . . . . . . . . 56
12. Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
DS982F2
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CS5490
LIST OF FIGURES
Figure 1. Oscillator Connections................................................................................................... 7
Figure 2. UART Serial Frame Format ........................................................................................... 7
Figure 3. Active Energy Load Performance.................................................................................. 8
Figure 4. Reactive Energy Load Performance.............................................................................. 9
Figure 5. IRMS Load Performance ............................................................................................... 9
Figure 6. Signal Flow for V, I, P, and Q Measurements ............................................................. 15
Figure 7. Low-rate Calculations .................................................................................................. 16
Figure 8. Power-on Reset Timing ............................................................................................... 18
Figure 9. Zero-crossing Level and Zero-crossing Output on DO ................................................ 19
Figure 10. Energy Pulse Generation and Digital Output Control ................................................ 20
Figure 11. Sag, Swell, & Overcurrent Detect.............................................................................. 21
Figure 12. Phase Sequence A, B, C for Rising Edge Transition ................................................ 22
Figure 13. Phase Sequence C, B, A for Rising Edge Transition ................................................ 23
Figure 14. Byte Sequence for Page Select................................................................................. 24
Figure 15. Byte Sequence for Register Read ............................................................................ 24
Figure 16. Byte Sequence for Register Write ............................................................................. 24
Figure 17. Byte Sequence for Instructions.................................................................................. 24
Figure 18. Byte Sequence for Checksum ................................................................................... 25
Figure 19. Calibration Data Flow ................................................................................................ 51
Figure 20. T Register vs. Force Temp ........................................................................................ 53
Figure 21. Typical Connection Diagram (Single-phase, Two-wire, Power Meter) ...................... 54
LIST OF TABLES
Table 1. POR Thresholds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Table 2. Command Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Table 3. Instruction Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
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CS5490
1. OVERVIEW
The CS5490 is a CMOS power measurement integrated circuit that uses two  analog-to-digital
converters to measure line voltage and current. The CS5490 calculates active, reactive, and apparent
power as well as RMS voltage and current and peak voltage and current. It handles other system-related
functions, such as energy pulse generation, voltage sag and swell, overcurrent and zero-crossing
detection, and line frequency measurement. A separate analog-to-digital converter is used for on-chip
temperature measurement.
The CS5490 is optimized to interface to current transformers, shunt resistors, or Rogowski coils for
current measurement, and to resistive dividers or voltage transformers for voltage measurement. Two
full-scale ranges are provided on the current input to accommodate different types of current sensors. The
CS5490’s two differential inputs have a common-mode input range from analog ground (GNDA) to the
positive analog supply (VDDA).
An on-chip voltage reference (typically 2.4 volts) is generated and provided at analog output, VREF±.
The digital output (DO) provides a variety of output signals and, depending on the mode selected,
provides energy pulses, zero-crossings, or other choices.
The CS5490 includes a UART serial host interface to an external microcontroller. The UART signals
include serial data input (RX) and serial data output (TX).
DS982F2
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CS5490
2. PIN DESCRIPTION
XOUT
XIN
RESET
IINIIN+
VIN+
VINVREF-
1
2
3
4
5
6
7
8
16
15
14
13
12
11
10
9
VDDD
MODE
RX
TX
DO
VDDA
GNDA
VREF+
Clock Generator
Crystal In
Crystal Out
2,1
XIN, XOUT — Connect to an external quartz crystal. Alternatively, an external clock can be
supplied to the XIN pin to provide the system clock for the device.
Control Pins and Serial Data I/O
Digital Output
12
Reset
3
Serial Interface
Operating Mode Select
13,14
DO — Configurable digital output for energy pulses, interrupt, energy direction, and
zero-crossings.
RESET — An active-low Schmitt-trigger input used to reset the chip.
TX, RX — UART serial data output/input.
15
MODE — Connect to VDDA for proper operation.
Voltage Input
6,7
VIN+, VIN- — Differential analog input for the voltage channel.
Current Input
5,4
IIN+, IIN- — Differential analog input for the current channel.
Voltage Reference Input
9,8
VREF+, VREF- — The voltage reference output and return.
16
VDDD — Decoupling pin for the internal digital supply.
Positive Analog Supply
11
VDDA — The positive analog supply.
Analog Ground
10
GNDA — Analog ground.
Analog Inputs/Outputs
Power Supply Connections
Internal Digital Supply
2.1 Analog Pins
2.1.2 Current Input
The CS5490 has two differential inputs, one for voltage
(VIN) and one for currentIIN). The CS5490 also has
two voltage reference pins (VREF) between which a
0.1µ bypass capacitor must be placed.
The output of the current-sensing shunt resistor or
transformer is connected to the IIN input pins of the
CS5490. To accommodate different current-sensing
elements, the current channel incorporates a
programmable gain amplifier (PGA) with two selectable
input gains, as described in the Config0 register
description 6.6.1 Configuration 0 (Config0) – Page 0,
Address 0 on page 31. There is a 10x gain setting and
a 50x gain setting. The full-scale signal level for the
current channel is ±50mV and ±250mV for 50x and 10x
gain settings, respectively. If the input signal is a sine
wave, the maximum RMS voltage is 35.35 mVRMS or
176.78mVRMS, which is approximately 70.7% of
maximum peak voltage.
2.1.1 Voltage Input
The output of the line voltage resistive divider or
transformer is connected to the VIN input of the
CS5490. The voltage channel is equipped with a 10x,
fixed-gain amplifier. The full-scale signal level that can
be applied to the voltage channel is ±250 mV. If the
input signal is a sine wave, the maximum RMS
voltage is 250mVp / 2  176.78mVRMS, which is
approximately 70.7% of maximum peak voltage.
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CS5490
2.1.3 Voltage Reference
2.2.2 Digital Output
The CS5490 generates a stable voltage reference of
2.4V between the VREF pins. The reference system
also requires a filter capacitor of at least 0.1µF between
the VREF pins.
The CS5490 provides a configurable digital output
(DO). It can be configured to output energy pulses,
interrupt, zero-crossings, or energy directions. Refer to
the description of the Config1 register in section 6.6
Register Descriptions on page 31 for more details.
The reference system is capable of providing a
reference for the CS5490 but has limited ability to drive
external circuitry. It is strongly recommended that
nothing other than the required filter capacitor is
connected to the VREF pins.
2.1.4 Crystal Oscillator
An external, 4.096MHz quartz crystal can be connected
to the XIN and XOUT pins as shown in Figure 1. To reduce system cost, each pin is supplied with an on-chip
load capacitor.
XIN
XOUT
2.2.3 UART Serial Interface
The CS5490 provides two pins, RX and TX, for
communication between a host microcontroller and the
CS5490.
2.2.3.1 UART
The CS5490 provides a two-wire, asynchronous,
full-duplex UART port. The CS5490 UART operates in
8-bit mode, which transmits a total of 10 bits per byte.
Data is transmitted and received LSB first, with one start
bit, eight data bits, and one stop bit.
IDLE
START
0
1
2
3
4
5
6
7
STOP
IDLE
DATA
C1 = 22pF
Figure 2. UART Serial Frame Format
The baud rate is defined in the SerialCtrl register. After
chip reset, the default baud rate is 600, if MCLK is
4.096MHz. The baud rate is based on the contents of
bits BR[15:0] in the SerialCtrl register and is calculated
as follows:
C2 = 22pF
Figure 1. Oscillator Connections
Alternatively, an external
connected to the XIN pin.
clock
source
can
be
2.2 Digital Pins
2.2.1 Reset Input
The active-low RESET pin, when asserted for longer
than 120µs, will halt all CS5490 operations and reset
internal hardware registers and states. When
de-asserted, an initialization sequence begins, setting
the default register values. To prevent erroneous,
noise-induced resets to the part, an external pull-up
resistor and a decoupling capacitor are necessary on
the RESET pin.
DS982F2
BR[15:0] = Baud Rate x (524288/MCLK)
or
Baud Rate = BR[15:0] / (524288/MCLK)
The maximum baud rate is 512K if MCLK is 4.096MHz.
The UART has two signals: TX and RX. TX is the serial
data output from the CS5490; RX is the serial data input
to the CS5490.
2.2.4 MODE Pin
The MODE pin must be tied to VDDA for normal
operation. The MODE pin is used primarily for factory
test procedures.
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CS5490
3. CHARACTERISTICS & SPECIFICATIONS
RECOMMENDED OPERATING CONDITIONS
Parameter
Positive Analog Power Supply
Specified Temperature Range
Symbol
VDDA
TA
Min
3.0
-40
Typ
3.3
-
Max
3.6
+85
Unit
V
°C
POWER MEASUREMENT CHARACTERISTICS
Parameter
Active Energy
(Note 1 & 2)
Reactive Energy
(Note 1 & 2)
Apparent Power
(Note 1 & 3)
Current RMS
(Note 1, 3, & 4)
Symbol
Min
Typ
Max
Unit
All Gain Ranges
Current Channel Input Signal Dynamic Range 4000:1
PAvg
-
±0.1
-
%
All Gain Ranges
Current Channel Input Signal Dynamic Range 4000:1
QAvg
-
±0.1
-
%
All Gain Ranges
Current Channel Input Signal Dynamic Range 1000:1
S
-
±0.1
-
%
All Gain Ranges
Current Channel Input Signal Dynamic Range 1000:1
IRMS
-
±0.1
-
%
Voltage Channel Input Signal Dynamic Range 20:1
VRMS
-
±0.1
-
%
PF
-
±0.1
-
%
Voltage RMS
(Note 1 & 3)
Power Factor
(Note 1 & 3)
All Gain Ranges
Current Channel Input Signal Dynamic Range 1000:1
Notes: 1. Specifications guaranteed by design and characterization.
2. Active energy is tested with power factor PF = 1.0. Reactive energy is tested with Sin() = 1.0. Energy error measured at system
level using single energy pulse. Where: 1) One energy pulse = 0.5Wh or 0.5Varh; 2) VDDA = +3.3V, TA = 25°C, MCLK = 4.096MHz;
3) System is calibrated.
3. Calculated using register values; N ≥ 4000.
4. IRMS error calculated using register values. 1) VDDA = +3.3V; TA = 25°C; MCLK = 4.096MHz; 2) AC offset calibration applied.
TYPICAL LOAD PERFORMANCE
•
•
•
Energy error measured at system level using single energy pulse; where 1 energy pulse = 0.5Wh or 0.5Varh.
IRMS error calculated using register values
VDDA = +3.3V; TA = 25°C; MCLK = 4.096MHz
1
Percent Error (%)
0.5
0
Lagging PF = 0.5
Leading PF = 0.5
PF = 1
-0.5
-1
0
500
1000
1500
2000
2500
3000
3500
4000
4500
Current Dynamic Range (x : 1)
Figure 3. Active Energy Load Performance
8
DS982F2
CS5490
1
Percent Error (%)
0.5
0
Lagging sin(੮) = 0.5
Leading sin(੮) = 0.5
sin(੮) = 1
-0.5
-1
0
500
1000
1500
2000
2500
3000
3500
4000
4500
Current Dynamic Range (x : 1)
Figure 4. Reactive Energy Load Performance
1
Percent Error (%)
0.5
0
IRMS
Error
IRMS Error
-0.5
-1
0
500
1000
1500
Current Dynamic range (x : 1)
Figure 5. IRMS Load Performance
DS982F2
9
CS5490
ANALOG CHARACTERISTICS
•
•
•
•
Min/Max characteristics and specifications are guaranteed over all Recommended Operating Conditions.
Typical characteristics and specifications are measured at nominal supply voltages and TA = 25°C.
VDDA = +3.3V ±10%; GNDA = 0V. All voltages with respect to 0V.
MCLK = 4.096MHz.
Parameter
Symbol
Min
Typ
Max
Unit
CMRR
80
-
-
dB
-0.25
-
VDDA
V
Analog Inputs (Current Channels)
Common Mode Rejection
(DC, 50, 60Hz)
Common Mode+Signal
Differential Full-scale Input Range
[(IIN+) – (IIN-)]
(Gain = 10)
(Gain = 50)
IIN
-
250
50
-
mVP
mVP
Total Harmonic Distortion
(Gain = 50)
THD
90
100
-
dB
Signal-to-Noise Ratio (SNR)
(Gain = 10)
SNR
-
80
80
-
dB
dB
-
-115
-
dB
(Gain = 50)
Crosstalk from Voltage Inputs at Full Scale
(50, 60Hz)
Crosstalk from Current Input at Full Scale
(50, 60Hz)
-
-115
-
dB
Input Capacitance
IC
-
27
-
pF
Effective Input Impedance
EII
30
-
-
k
Offset Drift (Without the High-pass Filter)
OD
-
4.0
-
µV/°C
-
9
2.2
-
µVRMS
µVRMS
Noise (Referred to Input)
(Gain = 10)
(Gain = 50)
NI
Power Supply Rejection Ratio
(60Hz)
(Gain = 10)
(Gain = 50)
PSRR
60
68
65
75
-
dB
dB
(DC, 50, 60Hz)
CMRR
80
-
-
dB
-0.25
-
VDDA
V
[(VIN+) – (VIN-)]
VIN
-
250
-
mVP
Total Harmonic Distortion
THD
80
88
-
dB
Signal-to-Noise Ratio (SNR)
SNR
-
73
-
dB
-
-115
-
dB
IC
-
2.0
-
pF
Effective Input Impedance
EII
2
-
-
M
Noise (Referred to Input)
NV
-
40
-
µVRMS
OD
-
16.0
-
µV/°C
PSRR
60
65
-
dB
T
-
±5
-
°C
(Note 7)
Analog Inputs (Voltage Channels)
Common Mode Rejection
Common Mode+Signal
Differential Full-scale Input Range
Crosstalk from Current Inputs at Full Scale
(50, 60Hz)
Input Capacitance
Offset Drift (Without the High-pass Filter)
Power Supply Rejection Ratio
(Note 7)
(60Hz)
(Gain = 10)
Temperature
Temperature Accuracy
10
(Note 6)
DS982F2
CS5490
Parameter
Symbol
Min
Typ
Max
Unit
PSCA
-
3.9
-
mA
PC
-
12.9
4.5
-
mW
mW
Power Supplies
Power Supply Currents (Active State)
IA+ (VDDA = +3.3V)
Power Consumption
(Note 5)
Notes:
Active State (VDDA = +3.3V)
Stand-by State
5.
6.
7.
All outputs unloaded. All inputs CMOS level.
Temperature accuracy measured after calibration is performed.
Measurement method for PSRR: VDDA = +3.3V, a 150mV (zero-to-peak) (60Hz) sinewave is imposed onto the +3.3V DC supply
voltage at the VDDA pin. The “+” and “-” input pins of both input channels are shorted to GNDA. The CS5490 is then commanded
to continuous conversion acquisition mode, and digital output data is collected for the channel under test. The (zero-to-peak) value
of the digital sinusoidal output signal is determined, and this value is converted into the (zero-to-peak) value of the sinusoidal
voltage (measured in mV) that would need to be applied at the channel’s inputs, in order to cause the same digital sinusoidal
output. This voltage is then defined as Veq PSRR is (in dB):
150
PSRR = 20  log ----------V eq
VOLTAGE REFERENCE
Parameter
Reference
Symbol
Min
Typ
Max
Unit
VREF
+2.3
+2.4
+2.5
V
(Note 9)
TCVREF
-
25
-
ppm/°C
(Note 10)
VR
-
30
-
mV
(Note 8)
Output Voltage
Temperature Coefficient
Load Regulation
Notes:
8.
It is strongly recommended that no connection other than the required filter capacitor be made to VREF±.
9.
The voltage at VREF± is measured across the temperature range. From these measurements the following formula is used to
calculate the VREF temperature coefficient:
VREF MAX – VREFMIN
1
TC VREF =  ------------------------------------------------------------  ----------------------------------------------  1.0  10 6 
VREF AVG
T A MAX – T A MIN
10.
DS982F2
Specified at maximum recommended output of 1µA sourcing. VREF is a very sensitive signal, the output of the VREF circuit has
a very high output impedance so that the 0.1µF reference capacitor provides attenuation even to low frequency noise, such as
50Hz noise on the VREF output. As such VREF intended for the CS5490 only and should not be connected to any external
circuitry. The output impedance is sufficiently high that standard digital multi-meters can significantly load this voltage. The
accuracy of the metrology IC can not be guaranteed when a multimeter or any component other than the 0.1µF capacitor is
attached to VREF. If it is desired to measure VREF for any reason other than a very course indicator of VREF functionality, Cirrus
recommends a very high input impedance multimeter such as the Keithley Model 2000 Digital Multimeter be used, but still cannot
guarantee the accuracy of the metrology with this meter connected to VREF.
11
CS5490
DIGITAL CHARACTERISTICS
•
•
•
•
Min / Max characteristics and specifications are guaranteed over all Recommended Operating Conditions.
Typical characteristics and specifications are measured at nominal supply voltages and TA = 25°C.
VDDA = +3.3V ±10%; GNDA = 0V. All voltages with respect to 0V.
MCLK = 4.096MHz.
Parameter
Master Clock Characteristics
XIN Clock Frequency
XIN Clock Duty Cycle
Filter Characteristics
Phase Compensation Range
Input Sampling Rate
Digital Filter Output Word Rate
High-pass Filter Corner Frequency
Input/Output Characteristics
High-level Input Voltage (All Pins)
Internal Gate Oscillator
Symbol
Min
Typ
Max
Unit
MCLK
2.5
40
4.096
-
5
60
MHz
%
-10.79
-
MCLK/8
MCLK/1024
2.0
+10.79
-
°
Hz
Hz
Hz
VIH
0.6(VDDA)
-
-
V
VIL
-
-
0.6
V
±1
0.5
0.5
±10
V
V
V
V
µA
(60Hz, OWR = 4000Hz)
(Both channels)
OWR
-3dB
Low-level Input Voltage (All Pins)
Input Leakage Current
Iin
VDDA-0.3
VDDA-0.3
-
3-state Leakage Current
IOZ
-
-
±10
µA
Digital Output Pin Capacitance
Cout
-
5
-
pF
High-level Output Voltage
(Note 12)
Low-level Output Voltage
(Note 12)
Notes:
12
DO, Iout = +10mA
Iout = +5mA
VOH
DO, Iout = -12mA
All Other Outputs, Iout = -5mA
VOL
11.
All measurements performed under static conditions.
12.
XOUT pin used for crystal only. Typical drive current<1mA.
DS982F2
CS5490
SWITCHING CHARACTERISTICS
•
•
•
•
Min / Max characteristics and specifications are guaranteed over all Recommended Operating Conditions.
Typical characteristics and specifications are measured at nominal supply voltages and TA = 25°C.
VDDA = +3.3V ±10%; GNDA = 0V. All voltages with respect to 0V.
Logic Levels: Logic 0 = 0V, Logic 1 = VDDA.
Parameter
Rise Times
(Note 13)
Fall Times
(Note 13)
Symbol
Min
Typ
Max
Unit
DO
Any Digital Output Except DO
trise
-
50
1.0
-
µs
ns
DO
Any Digital Output Except DO
tfall
-
50
1.0
-
µs
ns
XTAL = 4.096 MHz (Note 14)
tost
-
60
-
ms
Start-up
Oscillator Start-up Time
Notes:
13.
Specified using 10% and 90% points on waveform of interest. Output loaded with 50pF.
14.
Oscillator start-up time varies with crystal parameters. This specification does not apply when using an external clock source.
DS982F2
13
CS5490
ABSOLUTE MAXIMUM RATINGS
Parameter
DC Power Supplies
Input Current
(Note 15)
(Notes 16 and 17)
Input Current for Power Supplies
Symbol
Min
Typ
Max
Unit
VDDA
-0.3
-
+4.0
V
IIN
-
-
±10
mA
-
-
-
±50
-
Output Current
(Note 18)
IOUT
-
-
100
mA
Power Dissipation
(Note 19)
PD
-
-
500
mW
Input Voltage
(Note 20)
VIN
- 0.3
-
(VDDA) + 0.3
V
2 Layer Board
4 Layer Board
JA
-
140
70
-
°C/W
°C/W
Ambient Operating Temperature
TA
- 40
-
85
°C
Storage Temperature
Tstg
- 65
-
150
°C
Junction-to-Ambient Thermal Impedance
Notes:
15.
VDDA and GNDA must satisfy [(VDDA) – (GNDA)]  + 4.0V.
16.
Applies to all pins, including continuous overvoltage conditions at the analog input pins.
17.
Transient current of up to 100mA will not cause SCR latch-up.
18.
Applies to all pins, except VREF±.
19.
Total power dissipation, including all input currents and output currents.
20.
Applies to all pins.
WARNING:
Operation at or beyond these limits may result in permanent damage to the device.
Normal operation is not guaranteed at these extremes.
14
DS982F2
VIN±
PMF
4th Order
∆Σ
Modulator
x10
MUX
CS5490
DELAY
CTRL
IIR
SINC3
V
HPF
Phase
Shift
PC
...
CPCC[1:0]
...
FPCC[8:0]
...
SYS GAIN
Config 2
I DCOFF
IIN±
4th Order
∆Σ
Modulator
PGA
DELAY
CTRL
SINC3
VGAIN
IIR
Epsilon
...
VFLT[1:0]
IFLT[1:0]
...
2
P
I GAIN
HPF
INT
PMF
MUX
VDCOFF
Q
I
Registers
Figure 6. Signal Flow for V, I, P, and Q Measurements
4. SIGNAL FLOW DESCRIPTION
The signal flow for voltage, current measurement, and
the other calculations is shown in Figure 6.
The signal flow consists of a current and a voltage
channel. The current and voltage channels have
differential input pins.
4.1 Analog-to-Digital Converters
Both input channels use fourth-order delta-sigma
modulators to convert the analog inputs to single-bit
digital data streams. The converters sample at a rate of
MCLK/8. This high sampling provides a wide dynamic
range and simplifies anti-alias filter design.
4.2 Decimation Filters
The single-bit modulator output data is widened to 24
bits and down sampled to MCLK/1024 with low-pass
decimation filters. These decimation filters are
third-order Sinc filters. The filter outputs pass through
an IIR "anti-sinc" filter.
4.3 IIR Filter
The IIR filter is used to compensate for the amplitude
roll-off of the decimation filters. The droop-correction
filter flattens the magnitude response of the channel out
to the Nyquist frequency, thus allowing for accurate
measurements of up to 2kHz (MCLK = 4.096MHz). By
default, the IIR filters are enabled. The IIR filters can be
bypassed by setting the IIR_OFF bit in the Config2
register.
DS982F2
4.4 Phase Compensation
Phase compensation changes the phase of voltage
relative to current by adding a delay in the decimation
filters. The amount of phase shift is set by the PC
register bits CPCC[1:0] and FPCC[8:0] for the current
channel. For the voltage channel, only bits CPCC[1:0]
affect the delay.
Fine phase compensation control bits, FPCC[8:0],
provide up to 1/OWR delay in the current channel.
Coarse phase compensation control bits, CPCC[1:0],
provide an additional 1/OWR delay in the current
channel or up to 2/OWR delay in the voltage channel.
Negative delay in the voltage channel can be
implemented by setting longer delay in the current
channel than the voltage channel. For a OWR of
4000Hz, the delay range is ±500µs, a phase shift of
±8.99° at 50Hz and ±10.79° at 60Hz. The step size is
0.008789° at 50Hz and 0.010547° at 60Hz. For more
information about phase compensation, see section 7.2
Phase Compensation on page 52.
4.5 DC Offset & Gain Correction
The system and CS5490 inherently have component
tolerances, gain, and offset errors, which can be
removed using the gain and offset registers. Each
measurement channel has its own set of gain and offset
registers. For every instantaneous voltage and current
sample, the offset and gain values are used to correct
DC offset and gain errors in the channel (see section 7.
System Calibration on page 51 for more details).
15
CS5490
4.6 High-pass & Phase Matching Filters
Optional high-pass filters (HPF in Figure 6) remove any
DC component from the selected signal paths. Each
power calculation contains a current and voltage
channel. If an HPF is enabled in only one channel, a
phase-matching filter (PMF) should be applied to the
other channel to match the phase response of the HPF.
For AC power measurement, high-pass filters should be
enabled on the voltage and current channels. For
information about how to enable and disable the HPF or
PMF on each channel, refer to Config2 register
descriptions in section 6.6 Register Descriptions on
page 31.
4.7 Digital Integrators
Optional digital integrators (INT in Figure 6) are
implemented on the current channel to compensate for
the 90° phase shift and 20dB/decade gain generated
by the Rogowski coil current sensor. When a Rogowski
coil is used as the current sensor, the integrator (INT)
should be enabled on that current channel. For
information about how to enable and disable the INT on
the current channel, refer to Config2 register
descriptions in section 6.6 Register Descriptions on
page 31.
4.8 Low-rate Calculations
All the RMS and power results come from low-rate calculations by averaging the output word rate (OWR) instantaneous values over N samples, where N is the
value stored in the SampleCount register. The low-rate
interval or averaging period is N divided by OWR
(4000Hz if MCLK = 4.096MHz). The CS5490 provides
N

V
÷N
two averaging modes for low-rate calculations: Fixed
Number of Sample Averaging mode and Line-cycle
Synchronized Averaging mode. By default, the CS5490
averages with the Fixed Number of Samples Averaging
mode. By setting the AVG_MODE bit in the Config2 register, the CS5490 will use the Line-cycle Synchronized
Averaging mode.
4.8.1 Fixed Number of Samples Averaging
N is the preset value in the SampleCount register and
should not be set less than 100. By default, the
SampleCount
register
is
4000.
With
MCLK = 4.096 MHz, the averaging period is fixed at
N/4000 = 1 second, regardless of the line frequency.
4.8.2 Line-cycle Synchronized Averaging
When operating in Line-cycle Synchronized Averaging
mode, and when line frequency measurement is
enabled (see section 5.4 Line Frequency Measurement
on page 19), the CS5490 uses the voltage (V) channel
zero crossings and measured line frequency to
automatically adjust N such that the averaging period
will be equal to the number of half line-cycles in the
CycleCount register. For example, if the line frequency
is 51Hz, and the CycleCount register is set to 100, N will
be 4000  (100/2)/51 = 3921 during continuous
conversion. N is self-adjusted according to the line
frequency, therefore the averaging period is always
close to the whole number of half line-cycles, and the
low-rate calculation results will minimize ripple and
maximize resolution, especially when the line frequency
varies. Before starting a low-rate conversion in the
Line-cycle Synchronized Averaging mode, the
V RMS
Config 2
...
APCM
...
I ACOFF
÷N
+

-
IRMS
MUX

N
I
QOFF
N

Q
÷N
+

+
QAVG
X
POFF

N
P
S
÷N
+

+
Inverse
PAVG
X
Registers
+

+
X
PF
Figure 7. Low-rate Calculations
16
DS982F2
CS5490
SampleCount register should not be changed from its
default value of 4000, and bit AFC of the Config2
register must be set. During continuous conversion, the
host processor should not change the SampleCount
register.
4.8.3 RMS Current & Voltage
The root mean square (RMS in Figure 7) calculations
are performed on N instantaneous voltage and current
samples using Equation 1:
The APCM bit in the Config2 register controls which
method is used for apparent power calculation.
4.8.7 Peak Voltage & Current
Peak current (IPEAK) and peak voltage (VPEAK) are calculated over N samples and recorded in the corresponding channel peak register documented in the
register map. This peak value is updated every
N samples.
4.8.8 Power Factor
Power factor (PF) is active power divided by apparent
power, as shown below. The sign of the power factor is
determined by the active power. See Equation 4.
N–1
I RMS =
N–1
 I 2n
n=0
-------------------N
V RMS =
 V 2n
n=0
---------------------N
[Eq.1]
The instantaneous voltage and current samples are
multiplied to obtain the instantaneous power (P) (see
Figure 6). The product is then averaged over N samples
to compute active power (PAVG).
4.8.5 Reactive Power
Instantaneous reactive power (Q) is the sample rate
result obtained by multiplying instantaneous current (I)
by instantaneous quadrature voltage (Q). These values
are created by phase shifting instantaneous voltage (V)
90° using first-order integrators (see Figure 6). The gain
of these integrators is inversely related to line
frequency, so their gain is corrected by the Epsilon
register, which is based on line frequency. Reactive
power (QAVG) is generated by integrating the
instantaneous quadrature power over N samples.
4.8.6 Apparent Power
By default, the CS5490 calculates the apparent power
(S) as the product of RMS voltage and current. See
Equation 2:
S = V RMS  I RMS
[Eq.2]
The CS5490 also provides an alternate apparent power
calculation method. The alternate apparent power
method uses real power (PAVG) and reactive power
(QAVG) to calculate apparent power. See Equation 3.
DS982F2
Q AVG 2 + P AVG 2
[Eq.4]
4.9 Average Active Power Offset
4.8.4 Active Power
S =
P ACTIVE
PF = ---------------------S
[Eq.3]
The average active power offset register, POFF, can be
used to offset erroneous power sources resident in the
system not originating from the power line. Residual
power offsets are usually caused by crosstalk into the
current channel from the voltage channel, or from ripple
on the meter’s or chip’s power supply, or from
inductance from a nearby transformer.
These offsets can be either positive or negative,
indicating crosstalk coupling either in phase or out of
phase with the applied voltage input. The power offset
register can compensate for either condition.
To use this feature, measure the average power at no
load and take the measured result (from the PAVG
register), invert (negate) the value, and write it to the
associated power offset register, POFF.
4.10 Average Reactive Power Offset
The average reactive power offset register, QOFF, can
be used to offset erroneous power sources resident in
the system not originating from the power line. Residual
reactive power offsets are usually caused by crosstalk
into the current channel from the voltage channel, or
from ripple on the meter’s or chip’s power supply, or
from inductance from a nearby transformer.
These offsets can be either positive or negative,
depending on the phase angle between the crosstalk
coupling and the applied voltage. The reactive power
offset register can compensate for either condition. To
use this feature, measure the average reactive power at
no load. Take the measured result from the QAVG
register, invert (negate) the value and write it to the
reactive power offset register, QOFF.
17
CS5490
5. FUNCTIONAL DESCRIPTION
5.1 Power-on Reset (POR)
Table 1. POR Thresholds
The CS5490 has an internal power supply supervisor
circuit that monitors the VDDA and VDDD power
supplies and provides the master reset to the chip. If
any of these voltages are in the reset range, the master
reset is triggered.
Both the analog and the digital supply have their own
POR circuit. During power-up, both supplies have to be
above the rising threshold for the master reset to be
de-asserted.
Each POR is divided into 2 blocks: rough and fine.
Rough POR triggers the fine POR. Rough POR
depends only on the supply voltage. The trip point for
the fine POR is dependent on bandgap voltage for
precise control.
The POR circuit also acts as a brownout detect. The fine
POR detects supply drops and asserts the master reset.
The rough and fine PORs have hysteresis in their rise
and fall thresholds which prevents the reset signal from
chattering.
The following plot shows the POR outputs for each of
the power supplies. The POR_Fine_VDDA and
POR_Fine_VDDD signals are AND-ed to form the
actual power-on reset signal to the digital circuity. The
digital circuitry, in turn, holds the master reset signal for
130ms and then de-asserts the master reset.
VDDA
Vth5
Vth2
Vth1
Vth6
POR_Rough_VDDA
POR_Fine_VDDA
Vth4
VDDD
Typical POR
Threshold
VDDA
VDDD
Rising
Falling
Rough
Vth1 = 2.34V
Vth6 = 2.06V
Fine
Vth2 = 2.77V
Vth5 = 2.59V
Rough
Vth3 = 1.20V
Vth8 = 1.06V
Fine
Vth4 = 1.51V
Vth7 = 1.42V
5.2 Power Saving Modes
Power Saving modes for CS5490 are accessed through
the Host Instruction Commands (see 6.1 Host
Commands on page 24).
•
Standby: Powers down all the ADCs, rough buffer,
and the temperature sensor. Standby mode disables
the system time calculations. Use the wake-up
command to come out of standby mode.
• Wake-up: Clears the ADC power-down bits and
starts the system time calculations.
After any of these commands are completed, the DRDY
bit is set in the Status0 register.
5.3 Zero-crossing Detection
Zero-crossing detection logic is implemented in
CS5490. A low-pass filter can be enabled by setting
ZX_LPF bit in register Config2. The low-pass filter has
a cut-off frequency of 80Hz. It is used to eliminate any
harmonics and to help the zero-crossing detection on
the 50Hz or 60Hz fundamental component. The
zero-crossing level registers are used to set the
minimum threshold over which the channel peak has to
exceed in order for the zero-crossing detection logic to
function. There are two separate zero-crossing level
registers: VZXLEVEL is the threshold for the voltage
channels, and IZXLEVEL is the threshold for the current
channels.
Vth7
Vth8
Vth3
POR_Rough_VDDD
POR_Fine_VDDD
POR_Fine_VDDA
POR_Fine_VDDD
Master Reset
130ms
Figure 8. Power-on Reset Timing
18
DS982F2
CS5490
V(t), I(t)
If |VPEAK| > VZXLEVEL, then voltage zero-crossing detection is enabled.
If |IPEAK| > IZXLEVEL, then current zero-crossing detection is enabled.
If |VPEAK| ” VZXLEVEL, then voltage zero-crossing detection is disabled.
If |IPEAK| ” IZXLEVEL, then current zero-crossing detection is disabled.
VZXLEVEL
IZXLEVEL
t
DO
Zero-crossing output on DOx pin
Pulse width = 250μs
t
Figure 9. Zero-crossing Level and Zero-crossing Output on DO
5.4 Line Frequency Measurement
If the Automatic Frequency Calculation (AFC) bit in the
Config2 register is set, the line frequency measurement
on the voltage channel will be enabled. The line
frequency measurement is based on a number of
voltage channel zero crossings. This number is 100 by
default and configurable through the ZXNUM register
(see section 6.6.56 on page 50). The Epsilon register
will be updated automatically with the line frequency
information. The Frequency Update (FUP) bit in the
Status0 interrupt status register is set when the
frequency calculation is completed. When the line
frequency is 50Hz and the ZXNUM register is 100, the
Epsilon register is updated every one second with a
resolution of less than 0.1%. A larger zero-crossing
number in the ZXNUM register will increase line
frequency measurement resolution and period. Note
that the CS5490 line frequency measurement function
does not support the line frequency out of the range of
40Hz to 75Hz.
DS982F2
The Epsilon register is also used to set the gain of the
90° phase shift filter used in the quadrature power
calculation. The value in the Epsilon register is the ratio
of the line frequency to the output word rate (OWR). For
50Hz line frequency and 4000Hz OWR, Epsilon is
50/4000 (0.0125) (the default). For 60Hz line
frequency, it is 60/4000 (0.015).
5.5 Energy Pulse Generation
The CS5490 provides an independent energy pulse
generation (EPG) block in order to output active,
reactive, and apparent energy pulses on the digital
output pin (DO). The energy pulse frequency is
proportional to the magnitude of the power. The energy
pulse output is commonly used as the test output of a
power meter. The host microcontroller can also use the
energy pulses to easily accumulate the energy. Refer to
Figure 10.
19
CS5490
EPG_ON
(Config1)
MCLK
0000
P AVG
0010
0011
Q AVG
Reserved
0100
Q SUM
0101
S
0110
Reserved
S SUM
0111
Energy Pulse Generation (EPG)
P SUM
0001
1000
PULSE RATE
(PulseCtrl) EPGIN[3:0]
4
(PulseWidth) FREQ_RNG[3:0]
4
(PulseWidth) PW[7:0]
8
Reserved
0001
Reserved
0010
Reserved
0011
P Sign
0100
Reserved
0101
PSUM Sign
0110
Q Sign
0111
Reserved
1000
Q SUM Sign
1001
Reserved
1010
V Crossing
1011
I Crossing
1100
Reserved
1101
Hi-Z
1110
Interrupt
1111
DOMODE[3:0]
(Config1)
Digital Output Mux (DO)
0000
Reserved
DO_OD
(Config1)
DO
4
Figure 10. Energy Pulse Generation and Digital Output Control
After reset, the energy pulse generation block is
disabled (DOMODE[3:0] = Hi-Z). To output a desired
energy pulse to a DO pin, it is necessary to follow the
steps below:
1. Write to register PulseWidth (page 0, address 8) to
select the energy pulse width and pulse frequency
range.
2. Write to register PulseRate (page 18, address 28) to
select the energy pulse rate.
3. Write to register PulseCtrl (page 0, address 9) to
select the input to the energy pulse generation block.
4. Write ‘1’ to bit EPG_ON of register Config1 (page 0,
address 1) to enable the energy pulse generation
block.
5. Wait at least 0.1s.
6. Write bits DOMODE[3:0] of register Config1 to select
DO to output pulses from the energy pulse
generation block.
7. Send DSP instruction (0xD5) to begin continuous
conversion.
20
5.5.1 Pulse Rate
Before configuring the PulseRate register, the full-scale
pulse rate needs to be calculated, and the frequency
range needs to be specified through FREQ_RNG[3:0]
bits in the PulseWidth register. For example, if a meter
has the meter constant of 1000imp/kWh, a maximum
voltage (UMAX) of 240V, and a maximum current (IMAX)
of 100A, the maximum pulse rate is:
[1000x(240x100/1000)]/3600 = 6.6667Hz.
Assume the meter is calibrated with UMAX and IMAX,
and the Scale register contains the default value of 0.6.
After gain calibration, the power register value will be
0.36, which represents 240 x 100 = 24kW or 6.6667Hz
pulse output rate. The full-scale pulse rate is:
Fout = 6.6667/0.36 = 18.5185Hz.
Refer to section 6.6.6 Pulse Output Width (PulseWidth)
– Page 0, Address 8 on page 35. The FREQ_RNG[3:0]
bits should be set to b[0110].
DS982F2
CS5490
The CS5490 pulse generation block behaves as
follows:
•
The pulse rate generated by full-scale (1.0 decimal)
power register is
FOUT = (PulseRate x 2000)/2FREQ_RNG
•
The PulseRate register value is
PulseRate = (FOUT x 2FREQ_RNG)/2000
= (18.5186 x 64)/2000
= 0.5925952
= 0x4BDA29
5.5.2 Pulse Width
The PulseWidth register defines the Active-low time of
each energy pulse:
these to zero (default) disables the detect feature for the
given channel. The value is in output word rate (OWR)
samples. The predetermined level is set by the values
in the VSagLEVEL , VSwellLEVEL , and IOverLEVEL
registers.
For each enabled input channel, the measured value is
rectified and compared to the associated level register.
Over the duration window, the number of samples above
and below the level are counted. If the number of
samples below the level exceeds the number of samples
above, a Status0 register bit VSAG is set, indicating a
sag condition. If the number of samples above the level
exceeds the number of samples below, a Status0
register bit VSWELL or IOVER is set, indicating a swell
or overcurrent condition (see Figure 11).
Active-low = 250µs + (PulseWidth/64000).
By default, the PulseWidth register value is 1, and the
Active-low time of each energy pulse is 265.6µs. Note
that the pulse width should never exceed the pulse
period.
5.6 Voltage Sag, Voltage Swell, and
Overcurrent Detection
Voltage sag detection is used to determine when the
voltage falls below a predetermined level for a specified
interval of time (duration). Voltage swell and overcurrent
detection determine when the voltage or current rises
above a predetermined level for the duration.
The duration is set by the value in the VSagDUR ,
VSwellDUR , and IOverDUR registers. Setting any of
DS982F2
L e ve l
D u ra tio n
Figure 11. Sag, Swell, & Overcurrent Detect
21
CS5490
5.7 Phase Sequence Detection
Polyphase meters using multiple CS5490 devices may
be configured to sense the succession of voltage
zero-crossings and determine which phase order is in
service. The phase sequence detection within CS5490
involves counting the number of OWR samples from a
starting point to the next voltage zero-crossing rising
edge or falling for each phase. By comparing the count
for each phase, the phase sequence can be easily
determined: the smallest count is first, and the largest
count is last.
The phase sequence detection and control (PSDC)
register provides the count control, zero-crossing
direction and count results. Writing '0' to bit DONE and
'10110' to bits CODE[4:0] of the PSDC register followed
by a falling edge on the RX pin will initiate the phase
sequence detection circuit. The RX pin must be held low
for a minimum of 500ns. When the device is in UART
mode, it is recommended that a 0xFF command be
written to all parts to start the phase sequence
detection. Multiple CS5490 devices in a polyphase
meter must receive the register writing and the RX
falling edge at the same time so that all CS5490 devices
starts to count simultaneously. Bit DIR of PSDC register
specifies the direction of the next zero crossing at which
the count stops. If bit DIR is '0', the count stops at the
next negative-to-positive zero crossing. If bit DIR is '1',
the count stops at the next positive-to-negative zero
Write 0x16 to
PSDC Register
Start on the Falling
Edge on the RX Pin
2
crossing. When the count stops, the DONE bit will be
set by the CS5490, and then the count result of each
phase may be read from bits PSCNT[6:0] of the PSDC
register.
If the PSCNT[6:0] bits are equal to 0x00, 0x7F or
greater than 0x64 (for 50Hz) or 0x50 (for 60Hz), then a
measurement error has occurred, and the
measurement results should be disregarded. This could
happen when the voltage input signal amplitude is lower
than the amplitude specified in the VZXLEVEL register.
To determine the phase order, the PSCNT[6:0] bit
counts from each CS5490 are sorted in ascending
order. Figure 12 and Figure 13 illustrate how phase
sequence detection is performed.
Phase sequences A, B, and C for the default rising edge
transition are illustrated in Figure 12. The PSCNT[6:0]
bits from the CS5490 on phase A will have the lowest
count, followed by the PSCNT[6:0] bits from the
CS5490 on phase B with the middle count, and the
PSCNT[6:0] bits from the CS5490 on phase C with the
highest count.
Phase sequences C, B, and A for rising edge transition
are illustrated in Figure 13. The PSCNT[6:0] bits from
the CS5490 on phase C will have the lowest count,
followed by the PSCNT[6:0] bits from the CS5490 on
phase B with the middle count, and the PSCNT[6:0] bits
from the CS5490 on phase A with the highest count.
Phase A Channel
Stop
Phase A Count
0
-2
A
Phase B Channel
2
Stop
Phase B Count
0
-2
C
B
Phase C Channel
Stop
2
Phase C Count
0
-2
Figure 12. Phase Sequence A, B, C for Rising Edge Transition
22
DS982F2
CS5490
Write 0x16 to
PSDC Register
Start on the Falling
Edge on the RX Pin
Phase A Channel
Stop
2
Phase A Count
0
-2
C
Phase B Channel
Stop
2
Phase B Count
0
-2
A
B
Phase C Channel
Stop
2
Phase C Count
0
-2
Figure 13. Phase Sequence C, B, A for Rising Edge Transition
be write-protected from the calculation engine. Setting
5.8 Temperature Measurement
the DSP_LCK[4:0] bits to 0x09 disables the
The CS5490 has an internal temperature sensor, which
write-protection mode.
is designed to measure temperature and optionally
Setting the HOST_LCK[4:0] bits in the RegLock register
compensate for temperature drift of the voltage
to 0x16 enables the CS5490 HOST lockable registers to
reference. Temperature measurements are stored in
be write-protected from the serial interface. Setting the
the temperature register (T), which, by default, is
HOST_LCK[4:0]
bits
to
0x09
disables
the
configured to a range of ±128°C.
write-protection mode.
The application program can change the scale and
For registers that are DSP lockable, HOST lockable, or
range of the temperature (T) register by changing the
both, refer to sections 6.2 Hardware Registers
temperature gain (TGAIN) register and temperature
Summary (Page 0) on page 26, 6.3 Software Registers
offset (TOFF) register.
Summary (Page 16) on page 28, and 6.4 Software
The temperature (T) register updates every 2240 output
Registers Summary (Page 17) on page 29.
word rate (OWR) samples. The Status0 register bit TUP
5.10.2 Register Checksum
indicates when T is updated.
All the configuration and calibration registers are
5.9 Anti-creep
protected by checksum, if enabled. Refer to sections 6.2
The anti-creep (no-load threshold) is used to determine
Hardware Registers Summary (Page 0) on page 26, 6.3
if a no-load condition is detected. The |PSum| and |QSum|
Software Registers Summary (Page 16) on page 28,
are compared to the value in the no-load threshold
and 6.4 Software Registers Summary (Page 17) on
(LoadMin) register. If both |PSum| and |QSum| are less
page 29. The checksum for all registers marked with an
than this threshold, then PSum and QSum are forced to
asterisk symbol (*) is computed at the rate of OWR. The
zero. If SSum is less than the value in LoadMin register,
checksum result is stored in the RegChk register. After
then SSum is forced to zero.
the CS5490 has been fully configured and loaded with
the calibrations, the host microcontroller should keep a
5.10 Register Protection
copy of the checksum (RegChk_Copy) in its memory. In
To prevent the critical configuration and calibration
normal operation, the host microcontroller can read the
registers from unintended changes, the CS5490 provides
RegChk register and compare it with the saved copy of
two enhanced register protection mechanisms: write
the RegChk register. If the two values mismatch, a reload
protection and automatic checksum calculation.
of configurations and calibrations into the CS5490 is
5.10.1 Write Protection
necessary.
Setting the DSP_LCK[4:0] bits in the RegLock register
The automatic checksum computation can be disabled by
to 0x16 enables the CS5490 DSP lockable registers to
setting the REG_CSUM_OFF bit in the Config2 register.
DS982F2
23
CS5490
6. HOST COMMANDS AND REGISTERS
6.1 Host Commands
6.1.1.3 Register Write
The first byte sent to the CS5490 RX pin contains the
host command. Four types of host commands are
required to read and write registers and instruct the
calculation engine. The two most significant bits (MSBs)
of the host command defines the function to be
performed. The following table depicts the types of
commands.
A register write command is designated by setting the
two MSBs of the command to binary ‘01’. The lower 6
bits of the register write command are the lower 6 bits of
the 12-bit register address. A register write command
must be followed by 3 bytes of data.
Table 2. Command Format
Figure 16. Byte Sequence for Register Write
Function
Binary Value
Note
Register
Read
0 0 A5 A4 A3 A2 A1 A0
Register
Write
0 1 A5 A4 A3 A2 A1 A0
Page Select
1 0 P5 P4 P3 P2 P1 P0
P[5:0] specifies the
page.
Instruction
1 1 C5 C4 C3 C2 C1 C0
C[5:0] specifies the
instruction.
A[5:0] specifies the
register address.
6.1.1 Memory Access Commands
The CS5490 memory has 12-bit addresses and is
organized as P5 P4 P3 P2 P1 P0 A5 A4 A3 A2 A1 A0 in
64 pages of 64 addresses each. The higher 6 bits
specify the page number. The lower 6 bits specify the
address within the selected page.
6.1.1.1 Page Select
A page select command is designated by setting the two
MSBs of the command to binary ‘10’. The page select
command provides the CS5490 with the page number
of the register to access. Register read and write
commands access 1 of 64 registers within a specified
page. Subsequent register reads and writes can be
performed once the page has been selected.
RX
RX
RX
Instruction
Figure 17. Byte Sequence for Instructions
These new processes include calibration, power
control, and soft reset. The following table depicts the
types of instructions. Note that when the CS5490 is in
continuous conversion mode, an unexpected or invalid
instruction command could cause the device to stop
continuous conversion and enter an unexpected
operation mode. The host processor should keep
monitoring the CS5490 operation status and react
accordingly.
Table 3. Instruction Format
Function
Controls
TX
DATA
DATA
Binary Value
0 C4 C3 C2 C1 C0
0 00001 - Software Reset
0 00010 - Standby
0 00011 - Wakeup
0 10100 - Single Conv.
0 10101 - Continuous Conv.
0 11000 - Halt Conv.
Note
C[5] specifies
the instruction
type:
0 = Controls
1 = Calibrations
1 C4 C3 C2 C1 C0
6.1.1.2 Register Read
Read Cmd.
DATA
An instruction command is designated by setting the
two MSBs of the command to binary '11'. An instruction
command will interrupt any process currently running
and initiate a new process in the CS5490.
Figure 14. Byte Sequence for Page Select
RX
DATA
6.1.2 Instructions
Page Select Cmd.
A register read is designated by setting the two MSBs of
the command to binary ‘00’. The lower 6 bits of the read
register command are the lower 6 bits of the 12-bit
register address. After the register read command has
been received, the CS5490 will send 3 bytes of register
data onto the TX pin.
DATA
Write Cmd.
Calibration
1 00 C2C1C0
DC Offset
AC Offset*
1 10 C2C1C0
1 11 C2C1C0
Gain
*AC offset calibration valid
only for current channel.
For calibration,
C[4:3] specifies
the type of calibration.
1 C4 C3 C2 C1 C0
1 C4C3
1 C4C3
1 C4C3
001
010
110
I
V
I&V
For calibration,
C[2:0] specifies
the channel(s).
DATA
Figure 15. Byte Sequence for Register Read
24
DS982F2
CS5490
6.1.3 Checksum
To improve the communication reliability on the serial
interface, the CS5490 provides a checksum mechanism
on transmitted and received signals. Checksum is
disabled by default but can be enabled by setting the
appropriate bit in the SerialCtrl register. When enabled,
both host and CS5490 are expected to send one
additional checksum byte after the normal command
byte and applicable 3-byte register data have been
transmitted.
RX
The checksum is calculated by subtracting each
transmit byte from 0xFF. Any overflow is truncated and
the result wraps. The CS5490 executes the command
only if the checksum transmitted by the host matches
the checksum calculated locally. Otherwise, it sets a
status bit (RX_CSUM_ERR in Status0 register), ignores
the command, and clears the serial interface in
preparation for the next transmission.
RX
DS982F2
Page Select Cmd.
Checksum
Page Select
RX
Instruction
Checksum
Instruction
RX
Read Cmd.
CHECKSUM
TX
DATA
DATA
DATA
CHECKSUM
Read Command
Write Cmd.
DATA
DATA
DATA
CHECKSUM
Write Command
Figure 18. Byte Sequence for Checksum
6.1.4 Serial Time Out
In case a transaction from the host is not completed (for
example, a data byte is missing in a register write), a
time out circuit will reset the interface after 128ms. This
will require that each byte be sent from the host within
128ms of the previous byte.
25
CS5490
6.2 Hardware Registers Summary (Page 0)
Address2
0*
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
26
RA[5:0]
00 0000
00 0001
00 0010
00 0011
00 0100
00 0101
00 0110
00 0111
00 1000
00 1001
00 1010
00 1011
00 1100
00 1101
00 1110
00 1111
01 0000
01 0001
01 0010
01 0011
01 0100
01 0101
01 0110
01 0111
01 1000
01 1001
01 1010
01 1011
01 1100
01 1101
01 1110
01 1111
10 0000
10 0001
10 0010
10 0011
10 0100
10 0101
10 0110
10 0111
10 1000
10 1001
10 1010
10 1011
10 1100
10 1101
10 1110
10 1111
11 0000
11 0001
11 0010
11 0011
11 0100
Name
Config0
Config1
Mask
PC
SerialCtrl
PulseWidth
PulseCtrl
Status0
Status1
Status2
RegLock
VPEAK
IPEAK
PSDC
-
Description1
Configuration 0
Configuration 1
Reserved
Interrupt Mask
Reserved
Phase Compensation Control
Reserved
UART Control
Energy Pulse Width
Energy Pulse Control
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Interrupt Status
Chip Status 1
Chip Status 2
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Register Lock Control
Reserved
Peak Voltage
Peak Current
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Phase Sequence Detection & Control
Reserved
Reserved
Reserved
Reserved
DSP3
Y
Y
Y
Y
Y
Y
Y
N
N
N
N
N
N
N
-
HOST 3 Default
Y
0x C0 2000
Y
0x 00 EEEE
Y
0x 00 0000
Y
0x 00 0000
Y
0x 02 004D
Y
0x 00 0001
Y
0x 00 0000
N
0x 80 0000
N
0x 80 1800
N
0x 00 0000
N
0x 00 0000
Y
0x 00 0000
Y
0x 00 0000
Y
0x 00 0000
DS982F2
CS5490
53
54
55
56
57
58
59
60
61
62
63
Notes:
11 0101
11 0110
11 0111
11 1000
11 1001
11 1010
11 1011
11 1100
11 1101
11 1110
11 1111
ZXNUM
-
Reserved
Reserved
Num. Zero Crosses used for Line Freq.
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Y
-
Y
0x00 0064
-
(1) Warning: Do not write to unpublished or reserved register locations.
(2) * Registers with checksum protection.
(3) Registers that can be set to write protect from DSP and/or HOST.
DS982F2
27
CS5490
6.3 Software Registers Summary (Page 16)
Address2
0*
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
28
RA[5:0]
00 0000
00 0001
00 0010
00 0011
00 0100
00 0101
00 0110
00 0111
00 1000
00 1001
00 1010
00 1011
00 1100
00 1101
00 1110
00 1111
01 0000
01 0001
01 0010
01 0011
01 0100
01 0101
01 0110
01 0111
01 1000
01 1001
01 1010
01 1011
01 1100
01 1101
01 1110
01 1111
10 0000
10 0001
10 0010
10 0011
10 0100
10 0101
10 0110
10 0111
10 1000
10 1001
10 1010
10 1011
10 1100
10 1101
10 1110
10 1111
11 0000
11 0001
11 0010
11 0011
11 0100
Name
Config2
RegChk
I
V
P
PAVG
IRMS
VRMS
QAVG
Q
S
PF
T
PSUM
SSUM
QSUM
IDCOFF
IGAIN
VDCOFF
VGAIN
POFF
IACOFF
Epsilon
SampleCount
-
Description1
Configuration 2
Register Checksum
I Instantaneous Current
V Instantaneous Voltage
Instantaneous Power
Active Power
I RMS Current
V RMS Voltage
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reactive Power
Instantaneous Reactive Power
Reserved
Reserved
Reserved
Reserved
Apparent Power
Power Factor
Reserved
Reserved
Reserved
Reserved
Reserved
Temperature
Reserved
Total Active Power
Total Apparent Power
Total Reactive Power
I DC Offset
I Gain
V DC Offset
V Gain
Instantaneous Power Offset
I AC Offset
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Ratio of Line to Sample Frequency
Reserved
Sample Count
Reserved
DSP3
Y
N
N
N
N
N
N
N
HOST 3
Y
Y
Y
Y
Y
Y
Y
Y
N
N
Y
Y
N
N
Y
Y
N
Y
N
N
N
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
N
Y
N
Y
Default
0x 10 0200
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 00 0000
0x 40 0000
0x 00 0000
0x 40 0000
0x 00 0000
0x 00 0000
0x 01 999A
0x 00 0FA0
DS982F2
CS5490
53
54*
55*
56*
57
58*
59*
60*
61
62
63
Notes:
11 0101
11 0110
11 0111
11 1000
11 1001
11 1010
11 1011
11 1100
11 1101
11 1110
11 1111
TGAIN
TOFF
TSETTLE
LoadMIN
SYSGAIN
Time
-
Reserved
Temperature Gain
Temperature Offset
Reserved
Filter Settling Time to Conv. Startup
No Load Threshold
Reserved
System Gain
System Time (in samples)
Reserved
Reserved
Y
Y
Y
Y
Y
Y
Y
Y
N
N
Y
Y
0x 06 B716
0x D5 3998
0x 00 001E
0x 00 0000
0x 50 0000
0x 00 0000
-
(1) Warning: Do not write to unpublished or reserved register locations.
(2) * Registers with checksum protection.
(3) Registers that can be set to write protect from DSP and/or HOST.
6.4 Software Registers Summary (Page 17)
Address2
0*
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
RA[5:0]
00 0000
00 0001
00 0010
00 0011
00 0100
00 0101
00 0110
00 0111
00 1000
00 1001
00 1010
00 1011
00 1100
00 1101
00 1110
00 1111
01 0000
01 0001
01 0010
01 0011
01 0100
01 0101
01 0110
01 0111
01 1000
01 1001
01 1010
01 1011
01 1100
01 1101
01 1110
01 1111
Notes:
(1) Warning: Do not write to unpublished or reserved register locations.
Name
VSagDUR
VSagLevel
IOverDUR
IOverLEVEL
-
Description1
V Sag Duration
V Sag Level
Reserved
Reserved
I Overcurrent Duration
I Overcurrent Level
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
DSP3
Y
Y
Y
Y
HOST 3 Default
Y
0x 00 0000
Y
0x 00 0000
Y
0x 00 0000
Y
0x 7F FFFF
-
(2) * Registers with checksum protection.
(3) Registers that can be set to write protect from DSP and/or HOST.
DS982F2
29
CS5490
6.5 Software Registers Summary (Page 18)
Address2
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*
RA[5:0]
01 1000
01 1001
01 1010
01 1011
01 1100
01 1101
01 1110
01 1111
10 0000
10 0001
10 0010
10 0011
10 0100
10 0101
10 0110
10 0111
10 1000
10 1001
10 1010
10 1011
10 1100
10 1101
10 1110
10 1111
11 0000
11 0001
11 0010
11 0011
11 0100
11 0101
11 0110
11 0111
11 1000
11 1001
11 1010
11 1011
11 1100
11 1101
11 1110
11 1111
Notes:
(1) Warning: Do not write to unpublished or reserved register locations.
Name
IZXLEVEL
PulseRate
INTGAIN
VSwellDUR
VSwellLEVEL
VZXLEVEL
CycleCount
Scale
Description1
DSP3
I-channel Zero-crossing Threshold
Y
Reserved
Reserved
Reserved
Energy Pulse Rate
Y
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Rogowski Coil Integrator Gain
Y
Reserved
Reserved
V Swell Duration
Y
V Swell Level
Y
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
V-channel Zero-crossing Threshold
Y
Reserved
Reserved
Reserved
Line Cycle Count
N
Scale Value for I-channel Gain Calibration Y
HOST 3 Default
Y
0x 10 0000
Y
0x 80 0000
Y
0x 14 3958
Y
0x 00 0000
Y
0x 7F FFFF
Y
0x 10 0000
Y
0x 00 0064
Y
0x 4C CCCC
(2) * Registers with checksum protection.
(3) Registers that can be set to write protect from DSP and/or HOST.
30
DS982F2
CS5490
6.6 Register Descriptions
21.
“Default” = bit states after power-on or reset
22.
DO NOT write a “1” to any unpublished register bit or to a bit published as “0”.
23.
DO NOT write a “0” to any bit published as “1”.
24.
DO NOT write to any unpublished register address.
6.6.1 Configuration 0 (Config0) – Page 0, Address 0
23
1
22
1
21
0
20
0
19
-
18
-
17
-
16
-
15
-
14
0
13
1
12
-
11
-
10
-
9
-
8
INT_POL
7
-
6
-
5
IPGA[1]
4
IPGA[0]
3
-
2
NO_OSC
1
0
0
0
Default = 0xC0 2000
[23:9]
Reserved.
INT_POL
Interrupt Polarity.
0 = Active low (Default)
1 = Active high
[7:6]
Reserved.
IPGA[1:0]
Select PGA gain for I channel.
00 = gain (Default)
10 = 50x gain
[3]
Reserved.
NO_OSC
Disable crystal oscillator (making XIN a logic-level input).
0 = Crystal oscillator enabled (Default)
1 = Crystal oscillator disabled
DS982F2
31
CS5490
6.6.2 Configuration 1 (Config1) – Page 0, Address 1
23
0
22
0
21
0
20
EPG_ON
19
0
18
0
17
0
16
DO_OD
15
1
14
1
13
1
12
0
11
1
10
1
9
1
8
0
7
1
6
1
5
1
4
0
3
DOMODE[3]
2
DOMODE[2]
1
DOMODE[1]
0
DOMODE[0]
Default = 0x00 EEEE
32
[23:21]
Reserved.
EPG_ON
Enable EPG block.
0 = Disable energy pulse generation block (Default)
1 = Enable energy pulse generation block
[19:17]
Reserved.
DO_OD
Allow the DO pin to be an open-drain output.
0 = Normal output (Default)
1 = Open-drain output
[15:4]
Reserved.
DOMODE[3:0]
Output control for DO pin.
0000 = Energy pulse generation (EPG) block output
0001 = Reserved
0010 = Reserved
0011 = Reserved
0100 = P sign
0101 = Reserved
0110 = PSUM sign
0111 = Q sign
1000 = Reserved
1001 = QSUM sign
1010 = Reserved
1011 = V zero-crossing
1100 = I zero-crossing
1101 = Reserved
1110 = Hi-Z, pin not driven (Default)
1111 = Interrupt
DS982F2
CS5490
6.6.3 Configuration 2 (Config2) – Page 16, Address 0
23
-
22
POS
21
-
20
1
19
-
18
0
17
0
16
-
15
-
14
APCM
13
-
12
ZX_LPF
11
AVG_MODE
10
REG_CSUM_OFF
9
AFC
8
0
7
0
6
0
5
0
4
IFLT[1]
3
IFLT[0]
2
VFLT[1]
1
VFLT[0]
0
IIR_OFF
Default = 0x10 0200
[23]
Reserved.
POS
Positive energy only. Suppress negative values in PAVG . If a negative value is calculated,
a zero result will be stored.
0 = Positive and negative energy (Default)
1 = Positive energy only
[21:15]
Reserved.
APCM
Selects the apparent power calculation method.
0 = VRMS x IRMS (Default)
1 = SQRT(PAVG2 + QAVG2)
[13]
Reserved.
ZX_LPF
Enable LPF in zero-cross detect.
0 = LPF disabled (Default)
1 = LPF enabled
AVG_MODE
Select averaging mode for low-rate calculations.
0 = Use SampleCount (Default)
1 = Use CycleCount
REG_CSUM_OFF Disable checksum on critical registers.
0 = Enable checksum on critical registers (Default)
1 = Disable checksum on critical registers
AFC
Enables automatic line frequency measurement which sets Epsilon every time a new line
frequency measurement completes. Epsilon is used to control the gain of 90° phase shift
integrator used in quadrature power calculations.
0 = Disable automatic line frequency measurement
1 = Enable automatic line frequency measurement (Default)
[8:5]
Reserved.
IFLT[1:0]
Filter enable for current channel.
00 = No filter (Default)
01 = High-pass filter (HPF) on current channel
10 = Phase-matching filter (PMF) on current channel
11 = Rogowski coil integrator (INT) on current channel
VFLT[1:0]
Filter enable for voltage channel.
00 = No filter (Default)
01 = High-pass filter (HPF) on voltage channel
10 = Phase-matching filter (PMF) on voltage channel
11 = Reserved
IIR_OFF[0]
Bypass IIR filter.
0 = Do not bypass IIR filter (Default)
1 = Bypass IIR filter
DS982F2
33
CS5490
6.6.4 Phase Compensation (PC) – Page 0, Address 5
23
-
22
-
21
CPCC[1]
20
CPCC[0]
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
FPCC[8]
7
6
5
4
3
2
1
0
FPCC[7]
FPCC[6]
FPCC[5]
FPCC[4]
FPCC[3]
FPCC[2]
FPCC[1]
FPCC[0]
Default = 0x00 0000
[23:22]
Reserved.
CPCC[1:0]
Coarse phase compensation control for I & V.
00 = No extra delay
01 = 1 OWR delay in current channel
10 = 1 OWR delay in voltage channel
11 = 2 OWR delay in voltage channel
[19:9]
Reserved.
FPCC[8:0]
Fine phase compensation control for I & V.
Sets a delay in current, relative to voltage.
Resolution: 0.008789° at 50Hz and 0.010547° at 60Hz (OWR = 4000)
6.6.5 UART Control (SerialCtrl) – Page 0, Address 7
23
-
22
-
21
-
20
-
19
-
18
17
RX_PU_OFF RX_CSUM_OFF
16
-
15
BR[15]
14
BR[14]
13
BR[13]
12
BR[12]
11
BR[11]
10
BR[10]
9
BR[9]
8
BR[8]
7
BR[7]
6
BR[6]
5
BR[5]
4
BR[4]
3
BR[3]
2
BR[2]
1
BR[1]
0
BR[0]
Default = 0x02 004D
[23:19]
Reserved.
RX_PU_OFF
Disable the pull-up resistor on the RX input pin.
0 = Pull-up resistor enabled (Default)
1 = Pull-up resistor disabled
RX_CSUM_OFF Disable the checksum on serial port data.
0 = Enable checksum
1 = Disable checksum (Default)
34
[16]
Reserved.
BR[15:0]
Baud rate (serial bit rate).
BR[15:0] = Baud Rate x 524288 / MCLK
DS982F2
CS5490
6.6.6 Pulse Output Width (PulseWidth) – Page 0, Address 8
23
-
22
-
21
-
20
-
19
18
17
16
FREQ_RNG[3] FREQ_RNG[2] FREQ_RNG[1] FREQ_RNG[0]
15
PW[15]
14
PW[14]
13
PW[13]
12
PW[12]
11
PW[11]
10
PW[10]
9
PW[9]
8
PW[8]
7
6
5
4
3
2
1
0
PW[7]
PW[6]
PW[5]
PW[4]
PW[3]
PW[2]
PW[1]
PW[0]
Default = 0x00 0001 (265.6µs at OWR = 4kHz)
PulseWidth sets the energy pulse frequency range and the duration of energy pulses.
The actual pulse duration is 250µs plus the contents of PulseWidth divided by 64,000. PulseWidth is an integer in the range of 1 to 65,535.
[23:20]
Reserved.
FREQ_RNG[19:16] Energy pulse (PulseRate) frequency range for 0.1% resolution.
0000 = Freq. range:
2 kHz – 0.238 Hz (Default)
0001 = Freq. range:
1 kHz – 0.1192 Hz
0010 = Freq. range:
500 Hz – 0.0596 Hz
0011 = Freq. range:
250Hz–0.0298Hz
0100 = Freq. range:
125 Hz – 0.0149 Hz
0101 = Freq. range:
62.5 Hz – 0.00745 Hz
0110 = Freq. range:
31.25 Hz – 0.003725 Hz
0111 = Freq. range:
15.625 Hz – 0.0018626 Hz
1000 = Freq. range:
7.8125 Hz – 0.000931323 Hz
1001 = Freq. range:
3.90625 Hz – 0.000465661 Hz
1010 = Reserved
...
1111 = Reserved
PW[15:0]
Energy Pulse Width.
6.6.7 Pulse Output Rate (PulseRate) – Page 18, Address 28
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default= 0x80 0000
PulseRate sets the full-scale frequency for the energy pulse output.
For a 4 kHz OWR rate, the maximum pulse rate is 2 kHz. It is a two's complement value in the range of
-1  value  1, with the binary point to the left of the MSB.
Refer to section 5.5 Energy Pulse Generation on page 19 for more information.
DS982F2
35
CS5490
6.6.8 Pulse Output Control (PulseCtrl) – Page 0, Address 9
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
0
14
0
13
0
12
0
11
0
10
0
9
0
8
0
7
6
5
4
3
2
1
0
0
0
0
0
EPGIN[3]
EPGIN[2]
EPGIN[1]
EPGIN[0]
Default = 0x00 0000
This register controls the input to the energy pulse generation (EPG) block.
[23:4]
Reserved.
EPGIN[3:0]
Selects the input to the energy pulse generation (EPG) block.
0000 = PAVG (Default)
0001 = Reserved
0010 = PSUM
0011 = QAVG
0100 = Reserved
0101 = QSUM
0110 = S
0111 = Reserved
1000 = SSUM
1001 = Unused
...
1111 = Unused
6.6.9 Register Lock Control (RegLock) – Page 0, Address 34
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
DSP_LCK[4]
11
DSP_LCK[3]
10
DSP_LCK[2]
9
DSP_LCK[1]
8
DSP_LCK[0]
7
6
5
4
3
2
1
0
-
-
-
HOST_LCK[4] HOST_LCK[3] HOST_LCK[2] HOST_LCK[1] HOST_LCK[0]
Default = 0x00 0000
[23:13]
Reserved.
DSP_LCK[12:8] DSP_LCK[4:0] = 0x16 sets the DSP lockable registers to be write protected from the
CS5490 internal calculation engine. Writing 0x09 unlocks the registers.
[7:5]
Reserved.
HOST_LCK[4:0] HOST_LCK[4:0] = 0x16 sets all the registers except RegLock, Status0, Status1, and
Status2 to be write protected from the serial interface. Writing 0x09 unlocks the registers.
36
DS982F2
CS5490
6.6.10 Phase Sequence Detection and Control (PSDC) – Page 0, Address 48
23
DONE
22
PSCNT[6]
21
PSCNT[5]
20
PSCNT[4]
19
PSCNT[3]
18
PSCNT[2]
17
PSCNT[1]
16
PSCNT[0]
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
DIR
4
CODE[4]
3
CODE[3]
2
CODE[2]
1
CODE[1]
0
CODE[0]
Default = 0x00 0000
DONE
Indicates valid count values reside in PSCNT[6:0].
0 = Invalid values in PSCNT[6:0]. (Default)
1 = Valid values in PSCNT[6:0].
PSCNT[6:0]
Registers the number of OWR samples from the start time to the time when the next
zero crossing is detected.
[15:6]
Reserved.
DIR
Set the zero-crossing edge direction which will stop PSCNT count.
0 = Stop count at negative to positive zero-crossing - Rising Edge. (Default)
1 = Stop count at positive to negative zero-crossing - Falling Edge.
CODE[4:0]
Write 10110 to this location to enable the phase sequence detection.
6.6.11 Checksum of Critical Registers (RegChk) – Page 16, Address 1
MSB
223
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0000
This register contains the checksum of critical registers.
DS982F2
37
CS5490
6.6.12 Interrupt Status (Status0) – Page 0, Address 23
23
DRDY
22
CRDY
21
WOF
20
-
19
-
18
MIPS
17
-
16
VSWELL
15
-
14
POR
13
-
12
IOR
11
-
10
VOR
9
-
8
IOC
7
-
6
VSAG
5
TUP
4
FUP
3
IC
2
RX_CSUM_ERR
1
-
0
RX_TO
Default = 0x 00 0000
The Status0 register indicates a variety of conditions within the chip.
Writing a one to a Status0 register bit will clear that bit. Writing a zero to any bit has no effect.
DRDY
Data Ready. During conversion, this bit indicates that low-rate results have been updated.
It indicates completion of other host instruction and the reset sequence.
CRDY
Conversion Ready. Indicates that sample rate (output word rate) results have been updated.
WOF
Watchdog timer overflow.
[20:19]
Reserved.
MIPS
MIPS overflow.
Sets when the calculation engine has not completed processing a sample before the next
one arrives.
[17]
Reserved.
VSWELL
Voltage channel swell event detected.
[15]
Reserved.
POR
Power out of range. Sets when the measured power would cause the P register to overflow.
[13]
Reserved.
IOR
Current out of range. Set when the measured current would cause the I register to overflow.
[11]
Reserved.
VOR
Voltage out of range. Set when the measured voltage would cause the V register to overflow.
[7]
Reserved.
IOC
I Overcurrent.
[9]
Reserved.
VSAG
Voltage channel sag event detected.
TUP
Temperature updated. Indicates when the Temperature register (T) has been updated.
FUP
Frequency updated. Indicates the Epsilon register has been updated.
IC
Invalid command has been received.
RX_CSUM_ERR Received data checksum error. Sets to one automatically if checksum error is detected on
serial port received data.
RX_TO
38
SDI/RX time out. Sets to one automatically when SDI/RX time out occurs.
DS982F2
CS5490
6.6.13 Interrupt Mask (Mask) – Page 0, Address 3
23
DRDY
22
CRDY
21
WOF
20
-
19
-
18
MIPS
17
0
16
VSWELL
15
0
14
POR
13
0
12
IOR
11
0
10
VOR
9
0
8
IOC
7
0
6
VSAG
5
TUP
4
FUP
3
IC
2
RX_CSUM_ERR
1
-
0
RX_TO
Default = 0x00 0000
The Mask register is used to control the activation of the INT pin. Writing a '1' to a Mask register bit will allow
the corresponding Status0 register bit to activate the INT pin when set.
[23:0]
Enable/disable (mask) interrupts.
0 = Interrupt disabled (Default)
1 = Interrupt enabled
6.6.14 Chip Status 1 (Status1) – Page 0, Address 24
23
22
21
-
20
-
19
-
18
-
17
-
16
-
15
LCOM[7]
14
LCOM[6]
13
LCOM[5]
12
LCOM[4]
11
LCOM[3]
10
LCOM[2]
9
LCOM[1]
8
LCOM[0]
7
-
6
-
5
-
4
-
3
TOD
2
VOD
1
-
0
IOD
Default = 0x00 0000
This register indicates a variety of conditions within the chip.
[23:16]
Reserved.
LCOM[15:8]
Indicates the value of the last serial command executed.
[7:4]
Reserved.
TOD
Modulator oscillation has been detected in the temperature ADC.
VOD
Modulator oscillation has been detected in the voltage ADC.
[1]
Reserved.
IOD
Modulator oscillation has been detected in the current ADC.
DS982F2
39
CS5490
6.6.15 Chip Status 2 (Status2) – Page 0, Address 25
23
-
22
-
21
-
20
-
19
-
18
-
17
-
16
-
15
-
14
-
13
-
12
-
11
-
10
-
9
-
8
-
7
-
6
-
5
QSUM_SIGN
4
-
3
Q_SIGN
2
PSUM_SIGN
1
-
0
P_SIGN
Default = 0x00 0000
This register indicates a variety of conditions within the chip.
[23:6]
Reserved.
QSUM_SIGN
Indicates the sign of the value contained in QSUM.
0 = positive value
1 = negative value
[4]
Reserved.
Q_SIGN
Indicates the sign of the value contained in QAVG.
0 = positive value
1 = negative value
PSUM_SIGN
Indicates the sign of the value contained in PSUM.
0 = positive value
1 = negative value
[1]
Reserved.
P_SIGN
Indicates the sign of the value contained in PAVG.
0 = positive value
1 = negative value
6.6.16 Line to Sample Frequency Ratio (Epsilon) – Page 16, Address 49
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x01 999A (0.0125 or 50Hz/4.0kHz)
Epsilon is the ratio of the input line frequency to the output word rate (OWR).
It can either be written by the application program or calculated automatically from the line frequency (from
the voltage channel input) using the AFC bit in the Config2 register. It is a two's complement value in the range
of -1.0  value  1.0, with the binary point to the right of the MSB. Negative values are not used.
40
DS982F2
CS5490
6.6.17 No Load Threshold (LoadMIN) – Page 16, Address 58
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
LoadMIN is used to set the no-load threshold for the anti-creep function.
When the magnitudes of PSUM and QSUM are less than LoadMIN, PSUM and QSUM are forced to zero. When
the magnitude of SSUM is less than LoadMIN, SSUM is forced to zero.
LoadMIN is a two’s complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB. Negative values are not used.
6.6.18 Sample Count (SampleCount) – Page 16, Address 51
MSB
0
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0FA0 (4000)
Determines the number of output word rate (OWR) samples to use in calculating low-rate results.
SampleCount (N) is an integer in the range of 100 to 8,388,607. Values less than 100 should not be used.
6.6.19 Cycle Count (CycleCount) – Page 18, Address 62
MSB
0
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0064 (100)
Determines the number of half-line cycles to use in calculating low-rate results when the CS5490 is in Line-cycle Synchronized Averaging mode.
CycleCount is an integer in the range of 1 to 8,388,607. Zero should not be used.
6.6.20 Filter Settling Time for Conversion Startup (TSETTLE ) – Page 16, Address 57
MSB
223
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 001E (30)
Sets the number of output word rate (OWR) samples that will be used to allow filters to settle at the beginning
of Conversion and Calibration commands.
This is an integer in the range of 0 to 16,777,215 samples.
DS982F2
41
CS5490
6.6.21 System Gain (SysGAIN ) – Page 16, Address 60
MSB
-(21)
LSB
20
2-1
2-2
2-3
2-4
2-5
2-6
.....
2-16
2-17
2-18
2-19
2-20
2-21
2-22
Default = 0x50 0000 (1.25)
System Gain (SysGAIN ) is applied to all channels.
By default, SysGAIN = 1.25, but can be finely adjusted to compensate for voltage reference error. It is a two's
complement value in the range of -2.0  value  2.0, with the binary point to the right of the second MSB. Values should be kept within 5% of 1.25.
6.6.22 Rogowski Coil Integrator Gain (IntGAIN ) – Page 18, Address 43
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x14 3958
Gain for the Rogowski coil integrator. This must be programmed accordingly for 50Hz and 60Hz (0.158 for
50Hz, 0.1875 for 60Hz).
This is a two’s complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB. Negative values are not used.
6.6.23 System Time (Time) – Page 16, Address 61
MSB
223
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0000
System Time (Time) is measured in output word rate (OWR) samples.
This is an unsigned integer in the range of 0 to 16,777,215 samples. At OWR = 4.0 kHz, OWR will overflow
every 1 hour, 9 minutes, 54 seconds. Time can be used by the application to manage real-time events.
6.6.24 Voltage Sag Duration (VSagDUR ) – Page 17, Address 0
MSB
0
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0000
Voltage sag duration, VSagDUR, determines the count of output word rate (OWR) samples utilized to determine a sag event.
These are integers in the range of 0 to 8,388,607 samples. A value of zero disables the feature.
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6.6.25 Voltage Sag Level (VSagLEVEL ) – Page 17, Address 1
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Voltage sag level, VSagLEVEL, establishes an input level below which a sag event is triggered.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB. Negative values are not used.
6.6.26 Current Overcurrent Duration (IOverDUR ) – Page 17, Address 4
MSB
0
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0000
Overcurrent duration, IOverDUR, determines the count of output word rate (OWR) samples utilized to determine an overcurrent event.
These are integers in the range of 0 to 8,388,607 samples. A value of zero disables the feature.
6.6.27 Current Overcurrent Level (IOverLEVEL ) – Page 17, Address 5
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x7F FFFF
Overcurrent level, IOverLEVEL, establishes an input level above which an overcurrent event is triggered.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB. Negative values are not used.
6.6.28 Voltage Swell Duration (VSwellDUR ) – Page 18, Address 46
MSB
0
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0000
Voltage swell duration, VSwellDUR, determines the count of output word rate (OWR) samples used to determine a swell event.
These are integers in the range of 0 to 8,388,607 samples. A value of zero disables the feature.
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6.6.29 Voltage Swell Level (VSwellLEVEL ) – Page 18, Address 47
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x7F FFFF
Voltage swell level, VSwellLEVEL, establishes an input level above which a swell event is triggered.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB. Negative values are not used.
6.6.30 Instantaneous Current (I) – Page 16, Address 2
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
I contains instantaneous current measurements for current channel.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.31 Instantaneous Voltage (V) – Page 16, Address 3
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
V contains instantaneous voltage measurements for voltage channel.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.32 Instantaneous Active Power (P) – Page 16, Address 4
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
P contains instantaneous power measurements for current and voltage channels.
Values in registers I and V are multiplied to generate this value. This is a two's complement value in the range
of -1.0  value  1.0, with the binary point to the right of the MSB.
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6.6.33 Active Power (PAVG) – Page 16, Address 5
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Instantaneous power is averaged over each low-rate interval (SampleCount samples) and then added with
power offset (POFF) to compute active power (PAVG).
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.34 RMS Current (IRMS ) – Page 16, Address 6
MSB
2-1
LSB
2-2
2-3
2-4
2-5
2-6
2-7
2-8
.....
2-18
2-19
2-20
2-21
2-22
2-23
2-24
Default = 0x00 0000
IRMS contains the root mean square (RMS) values of I, calculated during each low-rate interval.
This is an unsigned value in the range of 0value1.0, with the binary point to the left of the MSB.
6.6.35 RMS Voltage (VRMS ) – Page 16, Address 7
MSB
2-1
LSB
2-2
2-3
2-4
2-5
2-6
2-7
2-8
.....
2-18
2-19
2-20
2-21
2-22
2-23
2-24
Default = 0x00 0000
VRMS contains the root mean square (RMS) value of V, calculated during each low-rate interval.
This is an unsigned value in the range of 0value1.0, with the binary point to the left of the MSB.
6.6.36 Reactive Power (QAvg ) – Page 16, Address 14
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Reactive power (QAVG) is Q averaged over each low-rate interval (SampleCount samples) and corrected by
QOFF.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
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6.6.37 Instantaneous Quadrature Power (Q) – Page 16, Address 15
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Instantaneous quadrature power, Q, the product of V shifted 90° and I.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.38 Peak Current (IPEAK) – Page 0, Address 37
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Peak current (IPEAK) contains the value of the instantaneous current 1 sample with the greatest magnitude
detected during the last low-rate interval.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.39 Peak Voltage (VPEAK) – Page 0, Address 36
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Peak voltage (VPEAK) contains the value of the instantaneous voltage sample with the greatest magnitude
detected during the last low-rate interval.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.40 Apparent Power (S) – Page 16, Address 20
MSB
0
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Apparent power 1 (S) is the product of VRMS and IRMS or SQRT(PAVG2 + QAVG2 ).
This is an unsigned value in the range of 0  value  1.0, with the binary point to the right of the MSB.
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6.6.41 Power Factor (PF) – Page 16, Address 21
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Power factor (PF) is calculated by dividing active power (PAVG) by apparent power (S).
The sign is determined by the active power (PAVG) sign.
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.42 Temperature (T) – Page 16, Address 27
MSB
LSB
-(27)
26
25
24
23
22
21
20
.....
2-10
2-11
2-12
2-13
2-14
2-15
2-16
Default = 0
T contains results from the on-chip temperature measurement.
By default, T uses the Celsius scale and is a two's complement value in the range of -128.0  value  128.0
(°C), with the binary point to the right of bit 16.
T can be rescaled by the application using the TGAIN and TOFF registers.
6.6.43 Total Active Power (PSUM ) – Page 16, Address 29
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
PSUM = PAVG
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.44 Total Apparent Power (SSUM ) – Page 16, Address 30
MSB
0
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
SSUM = S
This is an unsigned value in the range of 0value1.0, with the binary point to the right of the MSB.
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CS5490
6.6.45 Total Reactive Power (QSUM ) – Page 16, Address 31
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
QSUM = QAVG
This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of the
MSB.
6.6.46 DC Offset for Current (IDCOFF ) – Page 16, Address 32
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
DC offset registers IDCOFF are initialized to zero on reset. During DC offset calibration, selected registers are
written with the inverse of the DC offset measured. The application program can also write the DC offset register values. This is a two's complement value in the range of -1.0  value  1.0, with the binary point to the
right of the MSB.
6.6.47 DC Offset for Voltage (VDCOFF ) – Page 16, Address 34
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
DC offset registers VDCOFF are initialized to zero on reset. During DC offset calibration, selected registers are
written with the inverse of the DC offset measured. The application program can also write the DC offset register values. It is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right
of the MSB.
6.6.48 Gain for Current (IGAIN ) – Page 16, Address 33
MSB
21
LSB
20
2-1
2-2
2-3
2-4
2-5
2-6
.....
2-16
2-17
2-18
2-19
2-20
2-21
2-22
Default = 1.0
Gain register IGAIN is initialized to 1.0 on reset. During gain calibration, the IGAIN register is written with the
multiplicative inverse of the gain measured. This is an unsigned fixed-point value in the range of
0  value  4.0, with the binary point to the right of the second MSB.
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6.6.49 Gain for Voltage (VGAIN ) – Page 16, Address 35
MSB
LSB
21
20
2-1
2-2
2-3
2-4
2-5
2-6
.....
2-16
2-17
2-18
2-19
2-20
2-21
2-22
Default = 1.0
Gain register VGAIN is initialized to 1.0 on reset. During gain calibration, the VGAIN register is written with the
multiplicative inverse of the gain measured. This is an unsigned fixed-point value in the range of
0  value  4.0, with the binary point to the right of the second MSB.
6.6.50 Average Active Power Offset (POFF ) – Page 16, Address 36
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0
Average Active Power Offset (POFF) is added to the averaged active power to yield PAVG register results. It
can be used to reduce systematic energy errors. This is a two's complement value in the range of
-1.0  value  1.0, with the binary point to the right of the MSB.
6.6.51 Average Reactive Power Offset (QOFF ) – Page 16, Address 38
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x00 0000
Average Reactive Power Offset (QOFF) is added to the averaged active power to yield QAVG register results.
It can be used to reduce systematic energy errors. It is a two's complement value in the range of
-1.0 value 1.0, with the binary point to the right of the MSB.
6.6.52 AC Offset for Current (IACOFF ) – Page 16, Address 37
MSB
2-1
LSB
2-2
2-3
2-4
2-5
2-6
2-7
2-8
.....
2-18
2-19
2-20
2-21
2-22
2-23
2-24
Default = 0
AC offset register IACOFF is initialized to zero on reset. It is used to reduce systematic errors in the RMS results. This is an unsigned value in the range of 0  value  1.0, with the binary point to the left of the MSB.
6.6.53 Temperature Gain (TGAIN ) – Page 16, Address 54
MSB
LSB
27
26
25
24
23
22
21
20
.....
2-10
2-11
2-12
2-13
2-14
2-15
2-16
Default = 0x 06 B716
Register TGAIN is used to scale the Temperature register (T), and is an unsigned fixed-point value in the range
of 0.0value256.0, with the binary point to the right of bit 16.
Register T can be rescaled by the application using the TGAIN and TOFF registers. Refer to section 7.3 Temperature Sensor Calibration on page 53 for more information.
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6.6.54 Temperature Offset (TOFF ) – Page 16, Address 55
MSB
-(27)
LSB
26
25
24
23
22
21
20
.....
2-10
2-11
2-12
2-13
2-14
2-15
2-16
Default = 0xD5 3998
Register TOFF is used to offset the Temperature register (T), and is a two's complement value in the range of
-128.0value128.0 (°C), with the binary point to the right of bit 16.
Register T can be rescaled by the application using the TGAIN and TOFF registers. Refer to section 7.3 Temperature Sensor Calibration on page 53 for more information.
6.6.55 Calibration Scale (Scale) – Page18, Address 63
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x4C CCCC (0.6)
The Scale register is used in the gain calibration to set the level of calibrated results of I-channel RMS. During
gain calibration, the IRMS results register is divided into the Scale register. The quotient is put into the IGAIN
register. It is a two's complement value in the range of -1.0  value  1.0, with the binary point to the right of
the MSB. Negative values are not used.
6.6.56 Zero-crossing Number (ZXNUM) – Page 0, Address 55
MSB
223
LSB
222
221
220
219
218
217
216
.....
26
25
24
23
22
21
20
Default = 0x00 0064 (100)
ZXNUM is the number of zero crossings used for line frequency measurement. It is an integer in the range of
1 to 8,388,607. Zero should not be used.
6.6.57 V-channel Zero-crossing Threshold (VZXLEVEL) – Page 18, Address 58
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x10 0000 (0.125)
VZXLEVEL is the level that the peak instantaneous voltage must exceed for the zero-crossing detection to
function. This is a two's complement value in the range of -1.0  value<1.0, with the binary point to the right of
the MSB. Negative values are not used.
6.6.58 I-channel Zero-crossing Threshold (IZXLEVEL) – Page 18, Address 24
MSB
-(20)
LSB
2-1
2-2
2-3
2-4
2-5
2-6
2-7
.....
2-17
2-18
2-19
2-20
2-21
2-22
2-23
Default = 0x10 0000 (0.125)
IZXLEVEL is the level that the peak instantaneous current must exceed for the zero-crossing detection to function. This is a two's complement value in the range of -1.0  value<1.0, with the binary point to the right of the
MSB. Negative values are not used.
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7. SYSTEM CALIBRATION
samples that are averaged during a calibration. The
calibration procedure takes the time of N + TSETTLE
OWR samples. As N is increased, the calibration takes
more time, but the accuracy of the calibration results
tends to increase.
Component tolerances, residual ADC offset, and
system noise require a meter that needs to be calibrated
before it meets a specific accuracy requirement. The
CS5490 provides an on-chip calibration algorithm to
operate the system calibration quickly and easily.
Benefiting from the excellent linearity and low noise
level of the CS5490, a CS5490 meter normally only
needs one calibration at a single load point to achieve
accurate measurements over the full load range.
The DRDY bit in the Status0 register will be set at the
completion of calibration commands. If an overflow
occurs during calibration, other Status0 bits may be set
as well.
7.1 Calibration in General
7.1.1 Offset Calibration
The CS5490 provides DC offset and gain calibration
that can be applied to the instantaneous voltage and
current measurements and AC offset calibration, which
can only be applied to the current RMS calculation.
During offset calibrations, no line voltage or current
should be applied to the meter; the differential signal on
voltage inputs VIN± or current inputs IIN± of the CS5490
should be 0 volts.
Since the voltage and current channels have
independent offset and gain registers, offset and gain
calibration can be performed on any channel
independently.
7.1.1.1 DC Offset Calibration
The DC offset calibration command measures and
averages DC values read on specified voltage or
current channels at zero input and stores the inverse
result in the associated offset registers. This DC offset
will be added to instantaneous measurements in
subsequent conversions, removing the offset.
The data flow of the calibration is shown in Figure 19.
Note that in Figure 19 the AC offset registers and gain
registers affect the output results differently than the DC
offset registers. The DC offset and gain values are
applied to the voltage/current signals early in the signal
path; the DC offset register and gain register values
affect all CS5490 results. This is not true for the AC
offset correction. The AC offset registers only affect the
results of the RMS current calculation.
The gain register for the channel being calibrated
should be set to 1.0 prior to performing DC offset
calibration.
DC offset calibration is not required if the high-pass filter
is enabled on that channel because the DC component
will be removed by the high-pass filter.
The CS5490 must be operating in its active state and
ready to accept valid commands. Refer to section 6.1.2
Instructions on page 24 for different calibration
commands. The value in the SampleCount register
determines the number (N) of output word rate (OWR)
7.1.1.2 AC Offset Calibration
The AC offset calibration applies only to the current
channel. It measures the residual RMS values on the
current channel at zero input and stores the squared
V*, I*, P*, Q*
Registers
IN
Modulator

N
Filter
IDCOFF *, VDCOFF*
Registers
IGAIN*, VGAIN*
Registers

VRMS* , IRMS*
Registers
N
N
-1
I ACOFF *Ϯ Register
N
-1
* Denotes readable/writable register
Ϯ
Applies only to the current path (I1, I2)
DC
0.6(Scale *Ϯ)
RMS
RMS
Figure 19. Calibration Data Flow
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CS5490
result in the AC offset register. This AC offset will be
subtracted from RMS measurements in subsequent
conversions, removing the AC offset on the current
channel.
The AC offset register for the channel being calibrated
should first be cleared prior to performing the
calibration. The high-pass filter should be enabled if AC
offset calibration is used. It is recommended that
TSETTLE be set to 2000ms before performing an AC
offset calibration. Note that the AC offset register holds
the square of the RMS value measured during
calibration. Therefore, it can hold a maximum RMS
noise of 0xFFFFFF . This is the maximum RMS noise
that AC offset correction can remove.
7.1.2 Gain Calibration
Prior to executing the gain calibration command, gain
registers for any path to be calibrated (VGAIN, IGAIN)
should be set to ‘1.0,’ and TSETTLE should be set to
2000 ms. For gain calibration, a reference signal must
be applied to the meter. During gain calibration, the
voltage RMS result register (VRMS) is divided into ‘0.6,’
and the current RMS result register (IRMS) is divided into
the Scale register. The quotient is put into the
associated gain register. The gain calibration algorithm
attempts to adjust the gain register (VGAIN, IGAIN) such
that the voltage RMS result register (VRMS) equals ‘0.6,’
and the current RMS result register (IRMS) equals the
Scale register.
Note that for the gain calibration, there are limitations on
choosing the reference level and the Scale register
value. Using a reference or a scale that is too large or
too small can cause register overflow during calibration
or later during normal operation. Either condition can set
Status register bits IOR and VOR. The maximum value
that the gain register can attain is ‘4.’ Using
inappropriate reference levels or scale values may also
cause the CS5490 to attempt to set the gain register
higher than ‘4.’ Therefore, the gain calibration result will
be invalid.
The Scale register is ‘0.6’ by default. The maximum
voltage (UMAX Volts) and current (IMAX Amps) of the
meter should be used as the reference signal level if the
Scale register is ‘0.6.’ After gain calibration, ‘0.6’ of the
VRMS (IRMS) registers represents UMAX Volts (IMAX
Amps) for the line voltage (load current); ‘0.36’ of the
PAVG, QAVG, or S register represents UMAX × IMAX
Watts, Vars, or VAs for the active, reactive, or apparent
power.
If the calibration is performed with U MAX Volts and ICAL
Amps and ICAL < I MAX, the Scale register needs to be
scaled down to 0.6 × ICAL / IMAX before performing gain
calibration. After gain calibration, ‘0.6’ of the VRMS
register represents UMAX Volts, 0.6 x ICAL / IMAX of the
IRMS register represents ICAL Amps, and 0.36 x
ICAL / IMAX of the PAVG, QAVG, or S register represents
UMAX x ICAL Watts, Vars, or VAs.
7.1.3 Calibration Order
1) If the HPF option is enabled, then any DC component that may be present in the selected signal channel will be removed, and a DC offset calibration is not
required. However, if the HPF option is disabled, the
DC offset calibration should be performed.
When using high-pass filters, it is recommended that
the DC offset register for the corresponding channel
be set to 0. Before performing DC offset calibration,
the DC offset register should be set to 0, and the corresponding gain register should be set to 1.
2) If there is an AC offset in the IRMS calculation, the AC
offset calibration should be performed on the current
channel. Before performing AC offset calibration, the
AC offset register should be set to 0.
3) Perform the gain calibration.
4) If an AC offset calibration was performed (step 2),
then the AC offset may need to be adjusted to compensate for the change in gain (step 3). This can be
accomplished by restoring zero to the AC offset register and then performing an AC offset calibration.
The adjustment could also be done by multiplying the
AC offset register value that was calculated in step 2
by the gain calculated in step 3 and updating the AC
offset register with the product.
7.2 Phase Compensation
A phase compensation mechanism is provided to adjust
for meter-to-meter variation in signal path delays.
Phase offset between a voltage channel and its
corresponding current channel can be calculated by
using the power factor (PF) register after a conversion.
1) Apply a reference voltage and current with a lagging
power factor to the meter. The reference current
waveform should lag the voltage with a 60° phase
shift.
2) Start continuous conversion.
3) Accumulate multiple readings of the PF register.
4) Calculate the average power factor, PFavg.
5) Calculate phase offset = arccos(PFavg) - 60°.
52
DS982F2
CS5490
Once the phase offset is known, the CPCC and FPCC
bits for that channel are calculated and programmed in
the PC register.
CPCC bits are used if either
• The phase offset is more than 1 output word rate
(OWR) sample.
• More delay is needed on the voltage channel.
The compensation resolution is 0.008789° at 50Hz and
0.010547° at 60Hz at an OWR of 4000Hz.
7.3 Temperature Sensor Calibration
Temperature sensor calibration involves the adjustment
of two parameters: temperature gain (TGAIN) and
temperature offset (TOFF). Before calibration, TGAIN
must be set to 1.0 (0x 01 0000), and TOFF must be set
to 0.0 (0x 00 0000).
7.3.1 Temperature Offset and Gain Calibration
To obtain the optimal temperature offset (TOFF) register
value and temperature (TGAIN) register value, it is
necessary to measure the temperature (T) register at a
minimum of two points (T1 and T2) across the meter
operating temperature range. The two temperature
points must be far enough apart to yield reasonable
accuracy, for example 25 °C and 85° C. Obtain a linear
fit of these points ( y = m  x + b ), where the slope (m)
and intercept (b) can be obtained.
T2
Y= m •x +b
Force Temperature (°C)
6) If the phase offset is negative, then the delay should
be added only to the current channel. Otherwise, add
more delay to the voltage channel than to the current
channel to compensate for a positive phase offset.
m
T1
b
T Register Value
Figure 20. T Register vs. Force Temp
TOFF and TGAIN are calculated using the equations
below:
b
T OFF = ----m
T GAIN = m
DS982F2
53
CS5490
8. BASIC APPLICATION CIRCUITS
The CS5490 is configured to measure power in a
single-phase, two-wire single voltage and current
system, as illustrated in Figure 21. In this diagram, a
current transformer (CT) is used to sense the line load
current, and a resistive voltage divider is used to sense
the line voltage.
+3.3V
+3.3V
0.1µF
N
0.1µF
VDDA MODE VDDD
Line
Wh
+3.3V
1K
1K
5 x250K
DO
VIN27nF
27nF
VIN+
CS5490
RX
TX
½ R BURDEN
1K
CT
IIN+
4.096 MHz
XOUT
½ R BURDEN
27nF
1K
Application
Processor
XIN
27nF
IIN-
VREF+
0.1µF
VREF-
LOA D
+3.3V
10K
RESET
GNDA
0.1 µF
Figure 21. Typical Connection Diagram (Single-phase, Two-wire, Power Meter)
54
DS982F2
CS5490
9. PACKAGE DIMENSIONS
16 SOIC (150 MIL BODY) PACKAGE DRAWING
Dimension
A
A1
b
c
D
E
E1
e
L
Θ
aaa
bbb
ddd
MIN
-0.10
0.31
0.10
0.40
0°
mm
NOM
----9.90 BSC
6.00 BSC
3.90 BSC
1.27 BSC
--0.10
0.25
0.25
MAX
1.75
0.25
0.51
0.25
MIN
-0.004
0.012
0.004
1.27
8°
0.016
0°
inch
NOM
----0.390 BSC
0.236 BSC
0.154 BSC
0.05 BSC
--0.004
0.010
0.010
MAX
0.069
0.010
0.020
0.010
0.050
8°
Notes:
1.
2.
3.
4.
DS982F2
Controlling dimensions are in millimeters.
Dimensions and tolerances per ASME Y14.5M.
This drawing conforms to JEDEC outline MS-012, variation AC for standard 16 SOIC narrow body.
Recommended reflow profile is per JEDEC/IPC J-STD-020.
55
CS5490
10. ORDERING INFORMATION
Ordering Number
Container
CS5490-ISZ
Bulk
CS5490-ISZR
Tape & Reel
Temperature
Package
-40 to +85 °C
16-pin SOIC, Lead (Pb) Free
11. ENVIRONMENTAL, MANUFACTURING, & HANDLING INFORMATION
Part Number
Peak Reflow Temp
MSL Rating*
Max Floor Life
CS5490-ISZ
260 °C
3
7 Days
* MSL (Moisture Sensitivity Level) as specified by IPC/JEDEC J-STD-020.
12. REVISION HISTORY
Revision
Date
Changes
PP1
APR 2012
Preliminary release.
F1
APR 2012
Edited for content and clarity.
F2
JUN 2012
Updated ordering information.
Contacting Cirrus Logic Support
For all product questions and inquiries contact a Cirrus Logic Sales Representative.
To find the one nearest to you go to www.cirrus.com
IMPORTANT NOTICE
Cirrus Logic, Inc. and its subsidiaries (“Cirrus”) believe that the information contained in this document is accurate and reliable. However, the information is subject
to change without notice and is provided “AS IS” without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant
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does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale.
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Cirrus Logic, Cirrus, the Cirrus Logic logo designs, EXL Core, and the EXL Core logo design are trademarks of Cirrus Logic, Inc. All other brand and
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56
DS982F2
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