acam-messelectronic gmbH
is now
Member of the
ams Group
The technical content of this acam-messelectronic document is still valid.
Contact information:
Headquarters:
ams AG
Tobelbader Strasse 30
8141 Premstaetten, Austria
Tel: +43 (0) 3136 500 0
e-Mail: ams_sales@ams.com
Please visit our website at www.ams.com
�
®
Data Sheet
PCapØ1
Single-chip Solution for Capacitance Measurement
with Standard Firmware 03.01.02
July 15 th , 2013
Document-No: DB_PCapØ1-0301_en V0.6
�®
PCapØ1Ax-0301
Published by acam -messelectronic gmbh
©acam-messelectronic gmbh 2013
Legal note
The present manual (data sheet and guide) is still under development, which may result in
corrections, modifications or additions. acam cannot be held liable for any of its contents,
neither for accuracy, nor for completeness. The compiled information is believed correct,
though some errors and omissions are likely. We welcome any notification, which will be
integrated in succeeding releases.
The acam recommendations are believed useful, the firmware proposals and the
schematics operable, nevertheless it is of the customer‘s sole responsibility to modify, test
and validate them before setting up any production process.
acam products are not designed for use in medical, nuclear, military, aircraft, spacecraft
or lifesupport devices. Nor are they suitable for applications where failure may provoke
injury to people or heavy material damage. acam declines any liability with respect to such
non-intended use, which remains under the customer‘s sole responsibility and risk.
Military, spatial and nuclear use subject to German export regulations.
acam do not warrant, and it is not implied that the information and/or practice presented
here is free from patent, copyright or similar protection. All registered names and
trademarks are mentioned for reference only and remain the property of their respective
owners. The acam logo and the PicoCap logo are registered trademarks of acam messelectronic gmbh, Germany.
Support / Contact
For a complete listing of Direct Sales, Distributor and Sales Representative contacts, visit
the acam web site at:
http://www.acam.de/sales/distributors/
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�PCapØ1Ax-0301
For technical support you can contact the acam support team in the headquarters in
Germany or the Distributor in your country. The contact details of acam in Germany are:
support@acam.de
or by phone
+49-7244-74190.
Content
1
System Overview ........................................................................................ 1-1
1.1
Features ............................................................................................. 1-1
1.2
Applications ........................................................................................ 1-2
1.3
Block diagram ..................................................................................... 1-3
1.4
Part Numbers ..................................................................................... 1-3
2
Characteristics & Specifications ................................................................... 2-1
2.1
Electrical Characteristics ....................................................................... 2-2
2.2
CDC Precision ..................................................................................... 2-4
2.3
Internal RC-Oscillator ............................................................................ 2-9
2.4
RDC Precision ................................................................................... 2-11
2.5
Power Consumption ............................................................................ 2-12
2.6
Package Information ........................................................................... 2-13
3
Converter Frontend .................................................................................... 3-1
3.1
CDC Measuring Principle ....................................................................... 3-2
3.2
Important CDC Parameters .................................................................... 3-2
3.3
CDC External Circuitry ........................................................................... 3-4
3.4
Connecting the Capacitive Sensors .......................................................... 3-5
3.5
Selecting the Discharge Resistor ............................................................. 3-6
3.6
Compensation Measurement .................................................................. 3-7
3.7
RDC Temperature Measurement ............................................................. 3-9
4
Interfaces (Serial And Pulse-Density) .............................................................. 4-1
4.1
Serial Interfaces................................................................................... 4-2
4.2
PDM/PWM and GPIO ........................................................................... 4-7
5
Write & Read Registers .............................................................................. 5-1
5.1
Configuration & Parameter Registers ....................................................... 5-2
5.2
Explanations to Configuration Registers .................................................. 5-15
5.3
Read Registers .................................................................................. 5-20
6
DSP, Memory & Firmware ........................................................................... 6-1
6.1
DSP Management and Programming ........................................................ 6-2
6.2
Memory Map ....................................................................................... 6-4
1-3
�®
7
2
PCapØ1Ax-0301
6.3
Memory Management ........................................................................... 6-4
6.4
OTP Firmware programming ................................................................... 6-5
6.5
Getting Started .................................................................................... 6-6
Miscellaneous ........................................................................................... 7-1
7.1
Bug Report ......................................................................................... 7-2
7.2
Document History ................................................................................ 7-6
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�PCapØ1Ax-0301
1
System Overview
PCapØ1 is a dedicated Capacitance-to-Digital Conversion Digital Signal Processor. Its front
end is based on acam‘s patented ® principle. This conversion principle offers high
resolution at conversion times as short as 2 µs. Customers benefit from outstanding
flexibility for optimizing power consumption, resolution and speed.
The PCap01A can be used for grounded single and differential sensors as well as for
floating single and differential sensors. With grounded capacitors the stray capacitance
inside the chip will be compensated. With floating capacitors, further to the internal stray
capacitance, the external stray capacitances as well get compensated. Additionally, the
temperature can be measured by means of internal thermistors or external ones (platinum
or others). Before loading some firmware to it, the chip is not completely operable. Data
will end up in ALU instead of being transferred to processor and/or output. Under this
well as handling a very basic firmware called 03.01.xx; this basic or “standard“ firmware
calculates the capacitance and resistance ratios and transfers them to the data output
ports, still without doing such further possible processing like filtering and linearization. It
is provided free of charge with the chip, yet, it needs to be loaded via SPI or I2C.
For clarity, those aspects that are standard-firmware related have been marked with a
blue stripe in the margin. User-written firmware may behave differently here.
1.1
Features
Digital measuring principle in CMOS technology
Up to 8 capacitances in grounded mode
Up to 4 capacitances in floating mode
Compensation of internal (grounded) and external parasitic capacities (floating)
High resolution: up to 6 aF at 5 Hz and 10 pF base capacitance, or 17 bit
(potential- free and with zero bias voltage)
resolution at 5 Hz with 100 pF base capacitance and 10 pF excitation
High measurement rate: up to 500 kHz
Extremely low current consumption possible:
Down to 4 µA at 3 Hz with 13.4 bit resolution
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1-1
Firmware Related
circumstance, we chose to write a combined data sheet covering the hardware aspects as
�®
PCapØ1Ax-0301
High stability with temperature, low offset drift (down to 30 aF per Kelvin), low gain
drift when all compensation options are activated.
Dedicated ports for precision temperature measurement (with Pt1000 sensors,
the resolution is 0.005 K)
Serial interfaces (SPI or I2C compatible)
Self-boot capability
Single power supply (2.1 to 3.6 V)
No need for a clock
RISC processor core using Harvard architecture:
48 x 48 bit RAM Data
4k x 8 bit volatile program memory for high-speed operation (40 to 100
MHz)
4k x 8 bit non-volatile (OTP) program memory for normal speed operation
(up to 40 MHz)
1.2
1-2
Applications
Humidity sensors
Position sensors
Pressure sensors
Force sensors
Acceleration sensors
Inclination sensors
Tilt sensors
Angle sensors
Wireless applications
Level sensors
Microphones
MEMS sensors
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�PCapØ1Ax-0301
1.3
Block diagram
Figure 1-1: Block Diagram
1.4
Part Numbers
Ref.
Package
Name
Conditioning
MOQ
1613
-Dice-
PCap01A
Waffle Pack
100
1793
QFN32
PCap01AD
Tape-on-reel
500
1795
QFN24
PCap01AK
Tape-on-reel
500
Sample policy. Single Laboratory samples of packaged chips are available; concerning dice,
however, MOQ applies.
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1-3
�®
1-4
PCapØ1Ax-0301
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�PCapØ1Ax-0301
2
Characteristics & Specifications
2.1
Electrical Characteristics ....................................................................... 2-2
2.1.1
Absolute Maximum Ratings .............................................................. 2-2
2.1.2
Recommended Operating Conditions .................................................. 2-3
2.2
CDC Precision ..................................................................................... 2-4
2.2.1
RMS Noise and Resolution vs. Output Data Rate .................................. 2-4
2.2.2
RMS Noise vs. Supply Voltage ........................................................... 2-7
2.2.3
Voltage-Dependent Offset and Gain Error (PSRR) .................................. 2-7
2.2.4
Temperature-Dependent Offset and Gain Error ..................................... 2-8
2.3
Internal RC-Oscillator ............................................................................ 2-9
2.4
RDC Precision ................................................................................... 2-11
2.5
Power Consumption ............................................................................ 2-12
2.6
Package Information ........................................................................... 2-13
2.6.1
Dice - Pad Layout ......................................................................... 2-13
2.6.2
QFN Packages ............................................................................. 2-14
2.6.3
Pin-Out QFN32 and QFN24 Versions ................................................ 2-15
2.6.4
Pin/Pad Assignment ..................................................................... 2-16
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2-1
�®
PCapØ1Ax-0301
2.1
Electrical Characteristics
2.1.1
Absolute Maximum Ratings
Supply voltage V DD-to-GND
- 0.3 to 4.0 V
Storage temperature Tstg
- 55 to 150 °C
ESD rating (HBM), each pin
> 2 kV
Junction temperature (Tj)
max. 125 °C
OTP Data Retention Period
10 years at 95 °C temperature
2-2
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�PCapØ1Ax-0301
2.1.2
Recommended Operating Conditions
Table 2-1: Operating conditions
Quantity
Symbol
Supply voltage
V DD
Digital port voltage
V io_digital
Remarks
Min.
2.1
Relative to ground
–
0.6
HIGH LOW
LOW HIGH
Digital ports
switching level
Typ.
Analog port voltage
V io_analog
OTP Programming
voltage
V OTP
Between “VPP_OTP” port
and ground.
SPI bus frequency
f SPI-bus
Clock frequency for the 4wire SPI bus operation
3.3
Max.
Unit
3.6
V
V DD +0.6
≤ 3.6
V
V DD +0.6
≤ 3.6
V
7.0
V
20
MH
z
2.5
mA
0.3 *
V DD
0.7 *
V DD
0.6
6.5
0
Buffer strength
e.g. for the MISO line
I2C bus frequency
Speed (data rate) of the 2wire I2C bus operation
0
OTP Bit hold time
Bit hold time for OTP write
30
GPIO input rise time
100
kHz
500
µs
Rise time of the input
signal put to generalpurpose I/O
t.b.d
ns
GPIO output rise time
Rise time of the output
signal from a generalpurpose I/O
t.b.d.
ns
CDC discharge time
MR1
0
40
µs
0
100
µs
Junction temperature must
not exceed +125 °C
- 40
+ 125
°C
At VDD = 2.4V -/+ 0.3V
- 40
+ 125
°C
RDC discharge time
Junction
Temperature
Tj
Ambient Temperature T a
Overclocking the I2C bus is technically possible but within the sole responsibility of the
customer (a license may be necessary).
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2-3
�®
PCapØ1Ax-0301
2.2
CDC Precision
2.2.1
RMS Noise and Resolution vs. Output Data Rate
Table 2-2 Typical Capacitive Noise & Resolution vs. Output Data Rate, 10 pF Base + 1 pF Span, fast
settle, V = 3.0 V
Output
FLOATING
GROUNDED
Data
Fully compensated
Internally compensated
Rate [Hz]
RMS
Eff.
Eff.
RMS
Eff.
Eff.
Noise
Resolution 10 Resolution 1
Noise
Resolution 10 Resolution 1
[aF]
pF base [Bits] pF span [Bits]
[aF]
pF base [Bits] pF span [Bits]
5
6
20.7
17.3
6
20.7
17.3
10
13
19.6
16.2
11
19.8
16.5
25
20
18.9
15.6
17
19.2
15.8
100
39
18.0
14.6
22
18.8
15.5
250
72
17.1
13.8
29
18.4
15.1
1,000
157
16.0
12.6
66
17.2
13.9
3,500
290
15.1
11.8
139
16.1
12.8
7,000
420
14.5
11.2
176
15.8
12.5
10,000
495
14.3
11.0
246
15.3
12.0
Root mean-square (RMS) noise in aF as a function of output data rate in Hz, measured at
3.0 V supply voltage using the maximum possible sample size for in -chip averaging at the
minimum possible cycle time. Bit values are calculated as a binary logarithm of noise (in
attofarad) over the base and excitation capacitance values. The measurements hav e been
done with the PCap01 evaluation board, with fixed C0G ceramic capacitors.
Both, sensor and reference are connected “floating” or “grounded”, as indicated. When
floating, compensation mechanisms for both internal and external stray capacitance are
activated; when grounded, internal only.
2-4
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�PCapØ1Ax-0301
Table 2-3 Typical Capacitive Noise & Resolution vs. Output Data Rate, 33 pF Base + 3.3 pF Span,
fast settle, V = 3.0 V
Output
FLOATING
Data
Fully compensated
Rate [Hz]
RMS
Eff.
Noise
Resolution 33
[aF]
pF base [Bits]
GROUNDED
Internally compensated
Eff.
Resolution
3.3 pF span
[Bits]
RMS
Noise
[aF]
Eff.
Resolution 33
pF base [Bits]
Eff.
Resolution
3.3 pF span
[Bits]
5
18
20.8
17.5
12
21.4
18.1
10
26
20.3
17.0
16
21.0
17.7
25
42
19.6
16.3
28
20.2
16.8
100
79
18.7
15.4
50
19.3
16.0
250
134
17.9
14.6
75
18.7
15.4
1,000
321
16.6
13.3
176
17.5
14.2
3,500
546
15.9
12.6
325
16.6
13.3
7,000
756
15.4
12.1
508
16.0
12.7
10,000
1119
14.8
11.5
742
15.4
12.1
Table 2-4 Typical Capacitive Noise & Resolution vs. Output Data Rate, 100 pF Base + 10 pF Span,
fast settle, V = 3.0 V
Output
FLOATING
Data
Fully compensated
Rate [Hz]
RMS
Eff.
Noise
Resolution
[aF]
100 pF base
[Bits]
GROUNDED
Internally compensated
Eff.
Resolution 10
pF span [Bits]
RMS
Noise
[aF]
Eff.
Resolution
100 pF base
[Bits]
Eff.
Resolution
10pF span
[Bits]
5
71
20.4
17.1
106
19.8
16.5
10
91
20.1
16.7
133
19.5
16.2
25
185
19.0
15.7
226
18.8
15.4
100
321
18.2
14.9
350
18.1
14.8
250
543
17.5
14.2
480
17.7
14.3
1,000
1044
16.5
13.2
987
16.6
13.3
3,500
3320
14.9
11.6
1965
15.6
12.3
7,000
4226
14.5
11.2
3675
14.7
11.4
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2-5
�®
Figure 2-1 Typical Capacitive Noise vs. Output
Data Rate, with 10 pF Base Capacitance, V =
3.0 V
PCapØ1Ax-0301
Figure 2-2 Typical Capacitive Noise vs. Output
Data Rate, with 33 pF Base Capacitance, V =
3.0 V
Figure 2-3 Typical Capacitive Noise vs. Output
Data Rate, with 100 pF Base Capacitance, V =
3.0 V
2-6
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�PCapØ1Ax-0301
2.2.2
RMS Noise vs. Supply Voltage
Figure 2-4 RMS Noise vs. Supply Voltage
RMS Noise expressed in aF as a function of VDD power supply voltage.
The upper curve is for 1 kHz output data rate, the lower curve for 10 Hz.
Data acquired like before with 10 pF ceramic C0G capacitors connected “floating” in place
of reference and sensor. The excitation capacitor was a 1 pF ceramics C0G type.
2.2.3
Voltage-Dependent Offset and
Gain Error (PSRR)
Data acquired like before with 100 pF ceramic
C0G capacitors connected “floating” in place
of reference and sensor. The excitation
capacitor was a 10 pF ceramics C0G type.
The gain drift is the principal contribution to
the error; offset drift is negligible. No
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2-7
�®
PCapØ1Ax-0301
dependency on update rate has been detected.
Figure 2-5 Gain Error in % vs. Supply Voltage (Power Supply Rejection Ratio)
At present, power-supply rejection ratio is poor, so the component needs well-filtered,
stable supply voltages. Linear regulators will be indicated in most cases. The data
presented here have been acquired in such conditions.
Any switching regulator in the supply line must be separated from the chi p through a linear
voltage regulator, combined with some purposefully designed RC filter. Any drift and noise
in the supply line add error and noise to the output.
2.2.4
Temperature-Dependent Offset and Gain Error
Offset drift as a function of temperature at
3.0V supply voltage VDD. 10 pF base
capacitance, both sensor and reference, a
C0G ceramics capacitor each, connected
“floating”.
Offset Drift:
3.0 V: 9.5 aF/K
Figure 2-6 Offset Drift vs. Temperature
Gain drift as a function of temperature at
3.0V supply voltage VDD. 10 pF base
capacitance, both sensor and reference,
plus 4.7 pF span, with C0G ceramics
capacitors each, connected “floating”.
Offset Drift:
3.0 V: 13 ppm/K
2-8
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�PCapØ1Ax-0301
Figure 2-7 Gain Drift vs. Temperature
2.3
Internal RC-Oscillator
The integrated RC-Oscillator can be set in the range between 10 kHz and 200 kHz, in
which 50 kHz is the standard setting (see Register 1 description). The nominal frequency
e.g. 50 kHz has a standard deviation of +/-20 % over parts. More than that, the internal
oscillator is dependent on voltage and temperature.
For details of how to set RC oscillator by OLF_TUNE see register 1 description (Chapter
5).
Figure 2-8: RC oscillator frequency dependence on voltage and OLF_FTUNE setting
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2-9
�®
PCapØ1Ax-0301
Figure 2-9: RC oscillator frequency dependence on temperature and OLF_FTUNE setting 0-15
Figure 2-10: RC oscillator frequency dependence on temperature and OLF_FTUNE setting 0-2
2-10
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�PCapØ1Ax-0301
2.4
RDC Precision
Thermoresistive Coefficients Tk at 20 °C
Material
Tk
Internal polysilicon reference
-1.1ppm/K
Internal aluminum thermistor
2830 ppm/K
External PT1000 sensor
3830 ppm/K
Resolution with internal Al/PolySi at 20 °C
Measurement Conditions
R2/Rref typ.
RMS noise
R2/Rref
Typical RMS noise
Temperature(*)
No averaging, 2 fake measurements
0.825
50 ppm
25 mK
16-fold averaging, 8 fake measurements
0.823
10 ppm
5 mK
(*) after linearization in post-processing software
Typical Error with internal Al-thermometer after linearization and conversion into
temperature, assuming a linear relation between temperature and resistivity:
-20 °C < Temp. < 0 °C
290 mK
0 °C < Temp. < 80 °C
110 mK
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2-11
�®
2.5
PCapØ1Ax-0301
Power Consumption
Table 2-5 Total Current I [µA] as a function of speed (SEQTIME) and resolution (C_AVRG) in
Triggered Mode
SEQTIME
(data rate [Hz])
I [µA]
C_AVRG (RMS resolution [Bits])
1
4
16
64
128
256
512
1024
2048
(11.3)
(12.3)
(13.4)
(14.4)
(14.9)
(15.4)
(15.9)
(16.4)
(16.9)
150
13
(3.1)
4
4
4
5
10
10
55
80
12
(6.1)
4
5
7
10
20
35
80
150
11
(12.2)
5
6
9
22
40
80
160
10
(24.4)
6
8
15
44
82
160
9
(48.8)
8
12
27
85
160
8
(97.7)
12
20
49
163
7
(195.0)
20
35
93
6
(391.0)
36
65
178
5
(781.0)
67
124
4
(1560.0)
127
236
3
(3120.0)
229
2
(6250.0)
409
Table 2-6 Total Current I [µA] as a function of speed (SEQTIME) and resolution (C_AVRG) in
Continuous Mode (this mode yields highest possible speed/performance)
C_AVRG (RMS resolution [Bits])
I [µA]
1
4
16
64
128
256
512
1024
2048
(11.3)
(12.3)
(13.4)
(14.4)
(14.9)
(15.4)
(15.9)
(16.4)
(16.9)
515
275
204
185
182
181
180
180
179
Temperature measurement in addition to capacitive measurement will add between 2 and
10 µA approximately, depending on speed. Total consumption values below 30 µA may be
2-12
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�PCapØ1Ax-0301
obtained only when driving the on-chip 1.8 volts core supply generator in an energy-saving
mode (see section 5, register 10); ultimate microamp savings with DSP slowed down (see
section 5, register 8).
2.6
Package Information
2.6.1
Dice - Pad Layout
Die dimensions: 2.15 mm x 1.67 mm with pad pitch 120 µm, pad opening is 85 µm x 85
µm
Die thickness: 380 µm
Figure 2-11: Pad Layout
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2-13
�®
2.6.2
PCapØ1Ax-0301
QFN Packages
Figure 2-12: QFN package dimensions
Table 2-7: QFN Dimensions
Dimensions in mm
Device Name
Package
D, E
D2, E2 N
e
L
b
A
A3
PCap01-AD
QFN32
5.00
3.70
8
0.5
0.4
0.25
0.75/0.9
0.20
PCap01-AK
QFN24
4.00
2.70
6
0.5
0.35
0.25
0.75/0.9
0.20
Dimensioning and tolerances acc. to ASME Y14.5M-1994
2-14
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�PCapØ1Ax-0301
2.6.3
Pin-Out QFN32 and QFN24 Versions
-AD: All pins are available
Figure 2-13
-AK: Reduced number of capacitor ports, no external oscillator
Figure 2-11
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2-15
�®
Pin/Pad Assignment
Description
BUFFCAP
Connect microfarad bypass capacitance and nanofarad
bypass capacitance to GND. Bridge all BUFFCAP pins.
Bypassing is mandatory!
GND
Ground
IIC_EN
Put this to LOW or GND for use of SPI bus. Put it to HIGH or
VDD otherwise.
INTN
Optional. Interrupt line, low active
MISO_PG1
Serial interface data line, Master In - Slave Out (SPI only,
otherwise available as general-purpose port)
MOSI_SDA
Serial interface data line, Master Out - Slave In
OXIN
May be left open. Very exceptionally used for connecting a 4
to 20 MHz ceramics resonator or quartz.
OXOUT
Pin
Number
-AD
-AK
1
1
10
25
8
17
13
24
18
22
“CDC” or capacitive measurement ports. Connect reference
and sensors here, beginning with PCØ for the reference.
16
12
23
17
11
12
27
19
PC1
28
20
PC2
29
21
PC3
30
22
PC4
31
23
PC5
32
24
PC6
2
PG5
Leave unconnected if not used
PC0
Comment
Need to be connected in any
case
Pin
Leave unconnected if
not used
2.6.4
PCapØ1Ax-0301
2-16
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PC7
PCAUX
May be used for external discharge resistor.
PG2
General purpose I/O ports. PG4 and PG5 are output only,
others are configurable input or output.
PG3
PG4
3
26
15
11
14
10
13
9
5
3
�PCapØ1Ax-0301
“RDC” or temperature measurement ports. Connect one side
of the external resistive sensors here.
PT0
PT1
7
5
4
2
When there is an external resistive (temperature
measurement) reference, connect it here, otherwise this is the
place for a third resistive sensor.
8
6
PTOUT
For temperature measurement, connect the other side of the
resistive sensors and a 33 nF ceramics capacitor here.
9
7
SCK_SCL
Serial interface clock line
20
15
SSN_PG0
SPI interface chip select line, low active.
Alternatively general purpose I/O port.
21
16
VDD
VDD here, plus bypass capacitance to GND. Bypassing is
mandatory!
6
19
4
VPP_OTP
Set to 6.5 V during OTP programming. Set back to GND
rapidly after the end of the programming process. Keep pin
grounded for normal device operation. Apply a 470 kOhm
pull-down resistor to this pin.
18
14
GND ground
pad
The ground pad, bottom located, is internally connected to
ground. Parallel external grounding is not necessary
-
-
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Connect to
GND
PT2REF
2-17
�®
2-18
PCapØ1Ax-0301
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�PCapØ1Ax-0301
3
Converter Frontend
3.1
CDC Measuring Principle ....................................................................... 3-2
3.2
Important CDC Parameters .................................................................... 3-2
3.3
CDC External Circuitry ........................................................................... 3-4
3.4
Connecting the Capacitive Sensors .......................................................... 3-5
3.5
Selecting the Discharge Resistor ............................................................. 3-6
3.6
Compensation Measurement .................................................................. 3-7
3.7
RDC Temperature Measurement ............................................................. 3-9
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3-1
�®
3.1
PCapØ1Ax-0301
CDC Measuring Principle
The device uses “discharge time measurement” as a principle for measuring either
capacitance (the CDC unit) or resistivity (the RDC unit). It addresses all ports (PC...,PT...)
in time multiplex.
Figure 3-1 Cycle Time
3.2
Important CDC Parameters
An important notion is “cycle time”, the period of one elementary discharge -and-recharge
cycle, see figure 3-1.
The discharge time is given by the capacitors and the discharge resistor. The cycle time is
the time interval between two discharge time measur ements and is set by the user. The
relevant parameter is CMEAS_CYTIME in register 4. The user has to take care that the
charge time and therefore the cycle time is long enough. As default we recommend to
have the cycle time > 2 x discharge time. Otherwise, the capacitors do not get charged
sufficiently. Further, if the cycle time is less than the discharge time the CDC will show a
time-out.
Measurement results are deduced as follows; discharge time ratios equal sensor -toreference values:
This equation holds for the CDC, and is similar for the RDC.
3-2
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�PCapØ1Ax-0301
Figure 3-2 Charging-/ discharging cycles grounded, compensated, single or differential sensors
Figure 3-2 shows a CDC example with 7 single / 3 differential grounded sensors plus one
reference. One measurement block is made of a discharge time measurement for each
capacitor and an additional one for measuring the internal stray capacitances and
comparator delay (internal compensation). Figures 3-2 and 3-3 have symbolic meaning
only, explaining the principle. No realistic scope shots.
Figure 3-3 Charging-/ discharging cycles floating, compensated, single and differential sensors
Figure 3-3 shows a CDC example with one floating single sensor plus reference / one
floating differential sensor. One measurement block is made of 3 discharge time
measurements for each capacitor, including the external compensation measurement, and
an additional one for measuring the internal stray capacitances and comparator delay. See
section 3.6 for further details on the compensation.
Measurement rate or “output data rate” is inversely proportional to the cycle time and to
the sum of “fake block number” and “averaging sample size”. If neither fake blocks nor on chip averaging are requested, results will be updated after every “block”.
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3-3
�®
PCapØ1Ax-0301
Figure 3-4 Measurement cycle
Example 1:
2 single grounded sensors + reference, cycle time = 20 µs:
2 fake blocks + 4-fold averaging:
block period = 80 µs
measurement period = 480 µs
Maximum update rate = 2,083 Hz
Example 2:
1 single floating sensor + reference, cycle time = 20 µs:
2 fake blocks + 8-fold averaging:
block period = 140 µs
measurement period = 1400 µs
Maximum update rate = 714 Hz
3.3
CDC External Circuitry
Figure 3-5 shows the part of the schematic that is independent from capacitive sensor
configuration. Here an example with the SPI interface used.
Figure 3-5: Schematics with sensors not shown
3-4
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�PCapØ1Ax-0301
Note: Bypass capacitors should be ceramics type. Low noise operation is conditioned by a
good bypassing. Place bypass close to the pins.
3.4
Connecting the Capacitive Sensors
The capacitive-sensor part of the schematic:
Figure 3-6: Single sensors, floating, up to 3 sensors (C1 to C3) and one reference (C0)
Figure 3-7: Single sensors, grounded, up to 7 sensors and one reference
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3-5
�®
PCapØ1Ax-0301
Figure 3-8: Differential sensors, floating
Figure 3-9: Differential sensors, grounded.
3.5
Selecting the Discharge Resistor
The measurement is based on controlled discharging; within the CDC part, four selectable
discharge resistivities down to 10 kOhms in size are available (see figure 3 -10). They are
useful for base capacitances from zero up to approx. 3.5 nF. Not described in this short
manual is the possibility of extending the measuring range to even higher capacitance
values by connecting a small resistivity outside the chip.
3-6
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�PCapØ1Ax-0301
Figure 3-10: CDC Dimensioning
3.6
Compensation Measurement
With grounded capacitors the PCap01 offers the possibility to compensate for internal
parasitic capacitances and, having the same effect, the propagation delay of the
comparator. ACAM patents pending.
With floating capacitors we have the additional option to compensate external parasitic
capacitances against ground. On the PCB, the wire capacitance typically refers to ground.
For long wires, it is recommended to use shields which should be grounded at their PCB
side.
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3-7
�®
PCapØ1Ax-0301
Figure 3-11 shows how shielded cables should be connected for compensation of the external
parasitic capacitances.
Three measurements are necessary for each capacitor in case of fl oating sensors; this is
shown in figure 3-12
Figure 3-12 Floating capacitors, external compensation measurements, the three measurements
that are made for each floating capacitor.
For the internal compensation measurement, both switches A1 and A0 are open. Only the
internal parasitic capacitance and the comparator propagation delay will thus be
measured.
3-8
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�PCapØ1Ax-0301
Figure 3-13 Grounded/floating capacitors, internal compensation measurement
3.7
RDC Temperature Measurement
The chip device has two on-chip resistor elements for the measurement of temperature,
an aluminum strip with TK ≈ 2800 ppm/K as a sensor and a polysilicon resistor with TK
“close to zero” as a reference.
As an alternative, it is possible to connect the temperature sensor and reference resistor
externally. (In general the chip may support two external sensors, but this option is not
supported by 03.01 firmware).
In any case, it is mandatory to connect an external 33 nF capacitor, because the
temperature measurement, too, is discharge time based. For the capacitor, C0G ceramics
yields best performance, whilst X7R material yields fair results.
In principle, external and internal thermometers/reference may be mixed, e.g. an external
PT1000 may be compared to the internal Poly-Si resistor.
The selection between internal and external resistors is done by TMEAS_7BITS in register
6:
A)
External solution
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3-9
�®
PCapØ1Ax-0301
Configuration:
Register 4 = ’h XX XX 01 (CMEAS triggered)
Register 5 = ’h CX XX XX
Output data:
Ratio PT1000/Rref as R0/Rref in read register
Res10 (address 13).
Figure 3-14
RDC with external resistors
B)
Firmware Related
Register 6 = ’h 00 0C 40 (external resistors)
Completely internal solution
Configuration:
Register 4 = ’h XX XX 01 (CMEAS triggered)
Register 5 = ’h CX XX XX
Output data:
Ratio R[Al]/R[Si_poly] as R2/Rref in read register Res11
(address 14).
Figure 3-15
RDC with internal resistors
There are various trigger sources for the temperature measurement, set in register 4 by
parameter TMEAS_TRIG_SEL. We strongly recommend to use TMEAS_TRIG_SEL = 1,
trigger by capacitance measurement. With this setting, the temperature measurement
follows directly each Nth capacitance measurement, where N is set by parameter
TMEAS_TRIG_PREDIV in register 5. With TMEAS_TRIG_PREDIV = 0 the temperature
measurement is done with each capacitance measurement. With TMEAS_TRIG_SEL = 0
the temperature measurement is triggered by software, sending opcode ’h8E. If no opcode
is sent the temperature measurement is switched off.
3-10
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Firmware Related
Register 6 = ’h 00 43 40 (external resistors)
�PCapØ1Ax-0301
For low power applications, it is recommended to set the divider TMEAS_TRIG_PREDIV to
such a value that the temperature measurement is done maximum 10 times per second.
Figure 3-16 Temperature Measurement triggered by Capacitance Measurement (continuous mode)
Figure 3-17 Temperature Measurement triggered by Capacitance Measurement (Sequence timer
triggered)
Be aware that the resistivity measurement is based on an AC, not a DC, method. So,
cable between sensor and chip may contribute shift and noise through its inductance and
capacitance. Twisted shielded cable may be a good choice, in some cases an active shield
may help.
Issue a start command (op code 0x8C) and begin polling data or watching INTN. See
sections 5.3, 6.5.3 and 6.5.4 for details. What you read is R0/Rref or R2/Rref, a ratio
between two resistivities.
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3-11
�®
PCapØ1Ax-0301
External or internal sensors — you will need to calibrate either solution in a climate
chamber.
3-12
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�PCapØ1Ax-0301
4
Interfaces (Serial And Pulse-Density)
4.1
Serial Interfaces................................................................................... 4-2
4.1.1
Op codes ...................................................................................... 4-2
4.1.2
I C Compatible Interface .................................................................. 4-3
4.1.3
The 4-wire, SPI interface.................................................................. 4-5
4.2
2
PDM/PWM and GPIO ........................................................................... 4-7
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4-1
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4.1
PCapØ1Ax-0301
Serial Interfaces
For operation with a micro-controller, and also for programming the device, two s erial
interfaces are available. Only one interface is available at a time, selected through the
voltage applied to the pin “IIC_EN”. Both interfaces are limited to “slave” rank, and both
permit programming:
Pin IIC_EN is connected to GROUND
The 4-wire SPI interface is active. General-purpose I/O
pins PG0 and PG1 are not available (occupied by SPI).
Pin IIC_EN is connected to VDD
The 2-wire I2C interface is active and all general-pur-pose
I/O pins are available, including PG0 and PG1.
Remarks: The general-purpose I/O pins PG2 through PG5 are available in either case. If
no controller interface is needed, put IIC_EN to VDD, not to ground. You must not leave
this pin open.
Once programmed, the device can operate stand-alone. As both interfaces are limited to
slave rank, stand-alone operation with data transfer to an ancillary device (e.g. an LCD
converter or a D/A converter) will necessitate software implementation of a serial
protocol (contact ACAM for details).
4.1.1
Op codes
Table 4-1: 8-Bit Op Code Commands
’h88
Power-up reset. This command resets everything.
’h8A
“Initial” or “partial” reset, leaves the SRAM contents and registers unchanged. Resets
important parts of the device like the front-end and DSP
’h8C
Start a capacitance measurement sequence
’h84
Terminate the write-to-OTP process
’h8E
Start temperature measurement
4-2
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�PCapØ1Ax-0301
Table 4-2: 24-Bit Op Code Commands
Command
Byte 2
Byte 1
Byte 0
Write to SRAM
1 0 0 1 Address
Data
Read SRAM
0 0 0 1 Address
Data
Write to OTP
1 0 1 Address
Data
Read OTP
0 0 1 Address
Data
Table 4-3: 32-Bit Op Code Commands
Command
Byte 3
Byte 2
Byte 1
Byte 0
Write Config
1
1
Cf_Address
Registry Parameter
Read Results
0
1
Rs_Address
Measurement Results or
Measurement Results
For Cf_Address, see section 5.1 below, and for Rs_Address, section 5.3 below.
4.1.2
2
I C Compatible Interface
2
The present paragraph outlines the PCap01 device specific use of the I C interface. For a
2
general description of ACAM‘s subset of the I C interface see the dedicated data sheet.
See also the PCap01 bug report at the end of the present sheet.
The external master (PCap cannot be master) begins the communication by sending a
start condition, falling edge on the SDA line while SCL is HIGH. It stops the communication
by a stop condition, a rising edge on the SDA line while SCK is high. Data bits are
transferred with the rising edge of SCK.
2
On I C buses, every slave holds an individual 7-bit device address, The address always has
to be sent as the first byte after the start condition, the last bit indicating the direction of
the following data transfer.
Address byte:
MSB
LSB
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4-3
�®
1
0
1
PCapØ1Ax-0301
0
0
fixed
A1
A0
R/W
variable
Default address: A1 = A0 = 0
The address byte is followed by the opcode and eventually the payload. Each byte is
followed by an acknowledge bit (= 0). PCap01 has 8-bit, 24-bit and 32-bit opcodes, listed
in tables 4-1 to 4-3.
2
Figure 4-1: I C principle sequence
2
I C Write
During write transactions, the master alone sends data, the addressed slave just sends
the acknowledge bits. The master first sends the slave address plus the write bit. Then it
sends the PCap specific opcode including the register address in the slave. Finally it send s
the payload (“Data“).
2
Figure 4-2 I C Write, an example
2
I C Read
During read transactions, the direction of communication has to be commuted. Therefore,
the master sends again a start condition plus the slave address plus the read bit (instead
of the write bit) to switch into read mode. Figure 4-3 shows an example with opcode “read
4-4
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�PCapØ1Ax-0301
RAM“. The master sets a Not-Acknowledge (1) to indicate “end read“, “stop sending“ to
the slave.
2
Figure 4-3: I C Read
4.1.3
The 4-wire, SPI interface
Clock Polarity, Clock Phase and Bit Order. The following choices are necessary for
successful operation.
Table 4-4: SPI Clock Polarity, Clock Phase and Bit Order
SPI - Parameter
Description
Setting
CPOL
Clock polarity
0
CPHA
Clock phase
1
Mode
SPI Mode
1
DORD
Bit sequence order
0, MSB first
Timing conditions:
Figure 4-4: SPI Write
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4-5
�®
PCapØ1Ax-0301
Figure 4-5: SPI Read
Table 4-5: SPI timing parameters
Name
Symbol
VDD=2.2 V
VDD=3.0 V
VDD=3.6 V
Units
Serial clock frequency
fSPI-bus
10
17
20
MHz
Serial clock pulse width HI state
tpwh
50
30
25
ns
Serial clock pulse width LO state
tpwl
50
30
25
ns
SSN enable-to-valid latch
tsussn
10
8
7
ns
SSN pulse width between write
cycles
tpwssn
50
30
25
ns
Data setup time prior to clock edge
tsud
7
6
5
ns
Data hold time after clock edge
thd
5
4
3
ns
Data valid after clock edge
tvd
40
26
16
ns
4-6
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4.2
PDM/PWM and GPIO
Pulse-Density / Pulse Width Code Interfaces and General-Purpose Ports
The following table shows the different general purpose ports and their possible
assignment.
Table 4-6: General-Purpose Port Assignment:
External Port Name
Description
Direction in or out
PG0
SSN (in SPI-Mode)
in
DSPØ or DSP2
in(1) / out
FF0 or FF2
in(1)
Pulse0
out
MISO (in SPI-Mode)
out
DSP1 or DSP3
in(1) / out
FF1 or FF3
in(1)
Pulse1
out
DSPØ or DSP2
in(1) / out
FF0 or FF2
in(1)
Pulse0
out
INTN
out
DSP1 or DSP3
in(1) / out
FF1 or FF3
in(1)
Pulse1
out
PG4
DSP4 (output only)
out
PG5
DSP5 (output only)
out
PG1
PG2
PG3
(1) These ports provide an optional debouncing filter and an optional pull-up resistor.
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4-7
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PCapØ1Ax-0301
Firmware Related
There is a possibility to generate pulse width or pulse density code as outputs from the
chip, based on the measurement results and using standard firmware (or some other,
possibly derived from Standard). Any of the capacitance or temperature measurement
results can be used to generate the pulsed output, and the selection is made by setting
the pulse1_select (resp. pulse0_select) in register Param2. The pulse codes may be
output through general-purpose ports PGØ and PG1 (or two others). Destination ports ar e
to be configured as output using the PG_DIR_IN bits in Register 9.
As one can see from above, ports PGØ and PG1 are seemingly not available for pulse
output when assigned to the SPI interface. In most cases, though, where pulse outputs
are wanted, SPI interface is used for programming only. Hence, after programming, the
programmer is removed, pin/pad VPP_OTP is set LOW, and pin/pad IIC_EN is set HIGH.
Once this is done, all PG ports are available for general -purpose use and especially PG0,
PG1 for the pulses.
The pulse-modulated output signal can
be transformed into an analog voltage
through a Low Pass filter. The Pulse
Width Modulated output needs a low
pass filter of higher order, while for
Pulse Density Modulated signal a
simple LP filter is sufficient. Suggested
dimensioning is 220 kOhm / 100 nF,
which smoothes the ripple to less than
1 LSB.
Figure 4-6: PDM Output filtering
For generating the pulsed outputs, the frequency of the carrier clock signal is configurable
Firmware Related
to either 8 MHz or 1 MHz or 100 kHz. However, for best results, the “OLF_X2“ 100 kHz
clock is recommended. It can be selected through PI1_CLK_SEL (resp. PI0_CLK_SEL) in
Register 9. The resolution of the Pulse interface has to be configured through PI1_RES
(resp. PI0_RES) in Register 9. The result of measurement from capacitance or
4-8
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�PCapØ1Ax-0301
temperature is a 24-bit value. The DSP linearizes this 24 bit result to a 10 bit value
(assuming “10 bit resolution“ setting). The parameters Slope (m) and Offset (b) of the
linear function are configurable in Registers Param3 to Param5. Both, offset and slope
can be set to either positive or negative values. The setting of the slope and offset limits
the range of the output signal and hence determines the voltage range of the filtered
analog signal. A 10-bit resolution thus limits the result value between 0 and 1023. For
lower-bit resolutions, the range reduces accordingly. The following figure depicts how the
result is processed to generate the pulsed output.
The following figure shows a sample linear function and its parameters graphically. In this
graph, the result C1/C0 has been taken on the x-axis, assuming that this result is to be
pulse modulated. Here the value of m is positive and b is ne gative. 10 bit resolution has
been configured.
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4-9
Firmware Related
Figure 4-7: Pulse generation
�®
PCapØ1Ax-0301
Figure 4-8: PWM-PDM linearization
By setting the value of m and b, the linearization function limits the range of the output x
as shown. Values outside these limits are ignored. Thereby knowing the range in which the
results might change, the parameters of the linearization function can be fed accordingly.
The lower limit of the valid range corresponds to 0% modulation (all bits are 0), this is the
least possible value of the output (0). The upper limit of the valid range corresponds to
100% modulation (all bits are 1), and this is the maximum possible value of output. 10 bit
resolution implies that this maximum value is 1023. For lower bit resolutions, this
Firmware Related
maximum value will come down accordingly. In terms of voltage, the two limits correspond
to 0V and Vdd.
Applications:
A typical case would be outputting capacitance result through PG0 and temperature
result through PG1. Calculation and copying to the output registers must be
performed by firmware. See help windows in the dedicated PCap01 assembler code
editor.
Useful for applications for which reading the results out through the SPI/ I2C
interface is not suitable because of speed limitations or applications requiring an
analog output signal.
4-10
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�PCapØ1Ax-0301
A temperature-coded pulse stream could be low-pass filtered and then directly used
for temperature control.
Please note that the entire linearization task as described here is performed by firmware,
especially the standard firmware.
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4-11
��PCapØ1Ax-0301
5
Write & Read Registers
The PCap01Ax-V0301 with the standard firmware 03.01.xx offers 21 configuration and
parameter registers and 13 read registers. The configuration registers cannot be read
back. So, for communication test use the „Write to SRAM“ & „Read SRAM“ opcodes.
The configuration registers (address 0 through 10) directly set the hardware like CDC,
RDC, interfaces, clocks and DSP. The parameter registers (address 11 through 19) set
values in the firmware and therefore are firmware specific.
5.1
Configuration & Parameter Registers ....................................................... 5-2
5.2
Explanations to Configuration Registers .................................................. 5-15
5.2.1
Comments on Register 0 ............................................................... 5-15
5.2.2
Comments on Register 2 ............................................................... 5-16
5.2.3
Comments on Register 3 ............................................................... 5-17
5.2.4
Comments on Registers 3 and 4 (timing rules) .................................. 5-17
5.2.5
Comments on Registers 4 and 5 ..................................................... 5-18
5.2.6
Comments on Register 6 ............................................................... 5-18
5.2.7
Comments on Register 8 ............................................................... 5-19
5.2.8
Comments on Register 9 ............................................................... 5-20
5.3
Read Registers .................................................................................. 5-20
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5-1
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5.1
PCapØ1Ax-0301
Configuration & Parameter Registers
Firmware Related
Overview:
Address
Name
Description
Target
0
Register 0
OTP settings: MEMCOMP, ECC_MODE, AUTOBOOT_DIS,
MEM_LOCK_DIS
Hardware
1
Register 1
Fixed default
Hardware
2
Register 2
C-measurement settings: CMESS_PORT_EN, CMEAS_BITS,
RDCHG_INT_SEL
Hardware
3
Register 3
C-measurement settings: CY_CLK_SEL, SEQ_TIME,
CMEAS_FAKE, C_AVRG
Hardware
4
Register 4
C/T-measurement settings: CMEAS_STARTPIN,
CMEAS_TRIG_SEL, CMEAS_CYTIME, TMEAS_CYTIME,
TMEAS_STARTPIN, TMEAS_TRIG_SEL
Hardware
5
Register 5
T-measurement settings: T_AVRG, TMEAS_TRIG_PREDIV
Hardware
6
Register 6
T-measurement settings: TMEAS_FAKE, TMEAS_7BITS
Hardware
7
Register 7
Fixed default
Hardware
8
Register 8
DSP configuration : DSP_SRAM_SEL, DSP_START,
DSPSTARTONOVL, DSP_STARTONTEMP, DSP_STARTPIN,
DSP_FF_IN, DSP_WATCHDOG_LENGTH, DSP_MOFLO_EN,
DSP_SPEED, INT2PG2
Hardware
9
Register 9
GPIO settings: PG_DIR_IN, PG_PULL_UP, PI_EN,
PI1_CLK_SEL, PI0_CLK_SEL, PI1_RES, PI0_RES
Hardware
10
Register 10
Control of internal 1.8 V regulator
Hardware
11
Param0
Not used
Firmware
12
Param1
Not used
Firmware
13
Param2
Pulsed output setting: pulse_select
Firmware
14
Param3
Pulsed output setting: pulse0_slope
Firmware
15
Param4
Pulsed output setting: pulse0_offset
Firmware
16
Param5
Pulsed output setting: pulse1_slope
Firmware
17
Param6
Pulsed output setting: pulse1_offset
Firmware
18
Param7
C-measurement setting: differential
Firmware
19
Param8
Gain_Corr
Firmware
20
Register 20
RUNBIT
Hardware
5-2
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�PCapØ1Ax-0301
Register Description in Detail:
Bit number
15 14 13
parameter
12 11 10 9
8
7
6
5
4
3
2
1
0
1
0
0
1
0
1
0
1
0
9
8
7
6
5
4
param1
Recommended value
1
Register 0 (address 0):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
ECC_MODE
0
1
0
0
1
AUTOBOOT_DIS
3
2
1
MEM_LOCK_DIS
0
Parameter
Description
Settings
MEMCOMP
Bits 18 and 19 control the SRAM-to-OTPcomparison mechanism.
0
1
2
3
ECC_MODE
OTP-internal error detection and repair
mechanism.
0x00 = Disabled („single“); limit=4032 Byte
0x0F = „Double“ mode; limit=4032 Byte
0xF0 = „Quad“ mode; limit=1984 Byte
AUTOBOOT_DIS
Automatic self boot from OTP
0x0 = stand-alone operation and the device
then boots automatically from OTP.
0xF = slave operation and the device is
interface booted.
MEM_LOCK_DIS
=
=
=
=
disable
5 Byte
33 Byte
257 Byte
0x0 = activating the memory read-out
blocker, which helps preventing the
firmware from being read and thus
protects your intellectual property.
0xF = Readout remains un-blocked
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0
5-3
�®
PCapØ1Ax-0301
BYTE 0 (bits 7...0) cannot be written directly through the interface, but can only be copied
from the OTP. This is part of the memory-secrecy mechanism protecting the OTP against
reverse-engineering disassembly attempts.
Register 1 (address 1):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
LF_CLK_SEL
2
1
0
OLF_FTUNE
OLF_TUNE
0
0
1
Parameter
0
0
0
0
0
0
0
0
1
0
0
Describtion
OLF_TUNE
Setting of the internal oscillator frequency
0
0
0
0
1
0
0
0
1
0
Settings
0x35 - 10 kHz
0x22 - 50 kHz
0x13 - 100 kHz
0x04 - 200 kHz
Recommended default setting:
0x22 (50 kHz) default
Remark: The internal RC oscillator varies over voltage and temperature, please see
Chapter 2.
Register 2 (address 2):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
1
0
1
1
CMEAS_PORT_EN
5-4
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�PCapØ1Ax-0301
Parameter
Description
Settings
CMEAS_PORT_EN
CDC port mask
Bit 16 enables port PC0, bit 17 enables
PC1 and so forth.
CMEAS_SCHEME
Sensor connecting scheme, see section
3.4
For differential capacitors and only for
them, Param7 has to be set, too.
b‘00
b‘00
b‘01
b‘10
CMEAS_DUMMY_EN
Selection of mirror symmetric charge and
discharge for differential capacitors,
avoiding mechanical stress
0 = off
1 = activated
COMPENS_EXT_DIS
Turn off compensation measurement for
external parasitic capacitances
0 = external compensation activated
1 = external compensation disabled
COMPENS_INT_DIS
Turn off compensation measurement for
internal parasitic capacitances
0 = internal compensation activated
1 = internal compensation disabled
RDCHG_INT_SEL
Selection of internal discharge resistor
b‘100
b‘101
b‘110
b‘111
STRAYCOMP
Disabling of internal and/or external stray
capacitance compensation
00
01
10
11
-
=
=
=
=
grounded single capacitances
grounded differential caps (same)
floating single capacitances
floating differential capacitances
=
=
=
=
180 kOhm
90 kOhm
30 kOhm
10 kOhm
Both active
External stray compensation
Internal stray compensation
No compensation active
Register 3 (address 3):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
SEQ_TIME
0
0
0
9
8
7
6
5
4
3
2
C_AVRG
0
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5-5
1
0
�®
PCapØ1Ax-0301
Parameter
Description
Settings
SEQ_TIME
Sets the trigger period in timer-triggered
mode (register 4, TMEAS_TRIG_SEL = 2).
0 = off
Otherwise, if s = SEQ_TIME , the trigger
period will be 20 µs * 2 ^ (s+1) with 1 ≤ s
≤ 24.
CMEAS_FAKE
Sets the number of CDC fake blocks per
sequence, variable from zero to four.
00
01
10
11
C_AVRG
Sample size for averaging the CDC results.
Zero is ignored and counts as one.
The signal-to-noise ratio will approximately
improve proportionally to the square root of
C_AVRG
-
no fake measurement
1 fake block
2 fake blocks
4 fake blocks
Register 4 (address 4):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
0
0
0
4
CMEAS_CYTIME
0
0
Parameter
Description
Settings
CMEAS_STARTPIN
Selects the pin for pulse-triggered
capacitance measurement
0
1
2
3
=
=
=
=
PG0
PG1
PG2
PG3
CMEAS_TRIG_SEL
Selects the trigger source for the
capacitance measurement
0
1
2
3
=
=
=
=
softwaretrigger only
continuous mode
timer-triggered mode
pulse-triggered mode
5-6
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3
2
1
0
�PCapØ1Ax-0301
CMEAS_CYTIME
Sets the cycle time for the capacitance
measurement. See section 3 for details.
Clock period depends on OLF_TUNE.
Clock period = 20µs @ 50kHz
CDC cycle time =
CMEAS_CYTIME * clock period
TMEAS_CYTIME
Sets the cycle time for the temperature
measurement. With 33 nF and 1000 ohms
sensors, set 0.
0 = 140 µs (recommended)
1 = 280 µs
TMEAS_STARTPIN
Selects the pin for pulse-triggered
temperature measurement
0
1
2
3
TMEAS_TRIG_SEL
Selects the trigger source for the
temperature measurement.
Option 2 and 3 shall not be used.
0 = off/ opcode triggered
1 = CMEAS-triggered (by Cmeasurement, recommended)
2 = timer-triggered mode
3 = pulse-triggered mode
( CMEAS_CYTIME > 0 )
=
=
=
=
PG0
PG1
PG2
PG3
Begin with 0x041300 to be sure to get CDC values. Then increase or decrease your CDC
cycle time according to your needs (linear scale). For first CDC tests, the RDC is better
kept idle, that is why its trigger selector is kept zero.
Register 5 (address 5):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
TMEAS_TRIG_PREDIV
Parameter
Description
Settings
T_AVRG
Sample size for averaging of RDC values
0
1
2
3
(1 = no averaging)
(4-fold averaging)
(8-fold averaging)
(16-fold averaging)
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5-7
1
0
�®
PCapØ1Ax-0301
TMEAS_TRIG_PREDIV
Sets the occurence of RDC measurements
relative to CDC measurements.
Zero counts as one. Set zero for
hygrometers, because temperature
and humidity must be measured alike
/ Set 100...1k or more in pressure
sensors, because pressure may vary
quickly, much faster than
temperature.
Register 6 (address 6):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
0
0
1
0
0
0
0
0
0
3
2
1
0
TMEAS_7BITS
0
0
0
0
0
0
0
0
Parameter
Description
Settings
TMEAS_FAKE
Select number of fake measurements. The
0 = 2 dummy measurements
resolution/precision may be better when = 1, 1 = 8 dummy measurements
but you will loose speed.
TMEAS_7BITS
See dedicated paragraph 5.2.6 below
Register 7 (address 7):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
5-8
9
8
7
6
5
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4
�PCapØ1Ax-0301
0
0
0
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
9
8
7
6
5
4
3
2
1
0
0
0
1
1
Register 8 (address 8):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
DSP_STARTPIN
DSP_FF_IN
0
Parameter
Description
Settings
INT2PG2
Activate PG2 as an additional interrupt port
(for QFN24 packages, where no INTN pin is
available).
0 = INTN port only
1 = INTN and PG2 in parallel
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5-9
�®
PCapØ1Ax-0301
PG1_X_G3
Re-route pulse code. By default (=1), the
pulse code is output at ports PG0 and PG1.
Optionally, the pulse ports may be shifted to
PG2 and PG3.
PG0_X_G2
1 = PG1
0 = PG3
1 = PG0
0 = PG2
For bits 23 to 3, see dedicated data sheet DB_PCap01_DSP_e.pdf (to be downloaded from
www.acam.de); in that data sheet especially the sections 2.5 and 2.6
For bits 2 to 0, see dedicated chapter 5.2.7 below. Set 0x800030 to start with.
Register 9 (address 9):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
PG_DIR_IN
PG_PULL_UP
PI_EN
9
8
7
PI1_CLK_SEL
6
PI0_CLK_SEL
Parameter
Description
Settings
PG_DIR_IN
toggles outputs to inputs (PG3/bit23 to
PG0/bit20).
0 = output
1 = input
PG_PULL_UP
Activates pull-up resistors in PG0 to PG3
lines; useful for mechanical switches.
Bit
Bit
Bit
Bit
PI_EN
enables pulse-density or pulse-width mode
code generation. PWM0/PDM0 can be
output at ports PG0 or PG2. PWM1/PDM1
b‘xx01 = PWM0 on
b‘xx10 = PDM0 on
b‘01xx = PWM1 on
5-10
16
17
18
19
5
=
=
=
=
PG0
PG1
PG2
PG3
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4
3
2
1
0
�PCapØ1Ax-0301
Parameter
Description
Settings
can be output at ports PG1 or PG3.
b‘10xx = PDM1 on
PI0_CLK_SEL
Base frequency for the pulse code interfaces,
based on the internal low-frequency oscillator
(OLF) or the external high frequency oscillator
(OHF)
4
5
6
7
=
=
=
=
OHF * 2
OHF
OHF / 2
OHF / 4
PI1_RES
Resolution of the pulse code interfaces
0
1
2
3
=
=
=
=
7 bit
8 bit
9 bit
10 bit
9
8
PI1_CLK_SEL
PI0_RES
8 = OLF * 2
9 = OLF
10 = OLF / 2
11 = OLF / 4
Try 0xFF000F to get started
Register 10 (address 10):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
7
6
5
4
3
2
1
0
2
1
0
V_CORE_CTL
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
Parameter
Description
Settings
V_CORE_CTL
Controls the 1.8 V core voltage regulator.
The low-current setting permits a better
resolution but puts restrictions onto RDC
speed and timing. See examples in section
6.5.2 to 6.5.4
0x47 = Standard
0x87 = Low-current
Param0 (address 11): not used
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
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4
3
5-11
Firmware Related
0
�®
PCapØ1Ax-0301
Param1 (address 12): not used
23 22 21 20 19 18 17 16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
0
9
8
7
6
5
4
3
2
1
0
Param2 (address 13):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
pulse1_select
Parameter
Description
pulse0_select
pulse1_select
Select the source for the PDM/PWM
outputs
pulse0_select
Settings
Param3 (address 14):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
ware Related
pulse0_slope
Parameter
Description
Settings
pulse0_slope
Slope for pulse output 0.
Signed fixed-point number with 19 integer, 4
fractional digits
-524,288 to +524,288 in steps of
0.0625
5-12
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2
1
0
�PCapØ1Ax-0301
Param4 (address 15):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
2
1
0
pulse0_offset
Parameter
Description
Settings
pulse0_offset
Offset for pulse output 0.
signed fixed-point number with 22 integer, 1
fractional digits. The fractional digit is used
for mathematical rounding, it is not used for
the output.
-4,194,304 to + 4,194,303.5 in steps of
0.5
Param5 (address 16):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
2
1
0
2
1
0
Parameter
Description
Settings
pulse1_slope
Slope for pulse output 1.
Signed fixed-point number with 19 integer, 4
fractional digits
-524,288 to +524,288 in steps of
0.0625
Param6 (address 17):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
pulse1_offset
Parameter
Description
Settings
pulse1_offset
Offset for pulse output 1.
signed fixed-point number with 22 integer, 1
fractional digits. The fractional digit is used
-4,194,304 to + 4,194,303.5 in steps of
0.5
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5-13
Firmware Related
pulse1_slope
�®
PCapØ1Ax-0301
for mathematical rounding, it is not used for
the output.
Param7 (address 18):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
Parameter
Description
Settings
differential
Selects between single and differential
sensors
0 = Single
7
6
5
4
3
2
1
0
6
5
4
3
2
1
0
1 = Differential
Param8 (address 19):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
Gain_Corr
Parameter
Description
Gain_Corr
Multiplication factor for internal compensation 0 to 7.9999995
measurement. Unsigned fixed-point number
Standard value is h‘200000, meaning
with 3 integer and 21 fractional digits.
d‘1.000000
5-14
Settings
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�PCapØ1Ax-0301
Register 20 (address 20):
23 22 21 20 19 18 17 16 15 14 13 12 11 10
0
0
0
0
0
0
0
0
0
0
0
0
0
0
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
Parameter
Description
Settings
RUNBIT
RUNBIT=1 must be the last parameter
written. Please set RUNBIT=0 before making
any modifications to the registry.
0 = protects the device and keeps it idle
during configuration and forces the DSP to
stand still.
1 = activates the run mode
5.2
Explanations to Configuration Registers
5.2.1
Comments on Register 0
Register 0 is the first in the list, and the last to be handled, as it applies to the OTP
memory. So, during most of the evaluation and design-in, it will be unimportant.
MEMCOMP: Setting 0x0 is mandatory if DSP_SRAM_SEL=‘OTP‘. Otherwise 0x2 may be
best choice; upon firmware „stop“, the DSP clock will be slowed down, and SRA M contents
will be compared to OTP in 33-byte parcels. Next parcel after next stop. Upon comparison
alert, MEMCOMP issues a power-up reset. Through AUTOBOOT, the SRAM contents will be
refreshed.
ECC_MODE. When not disabled („single“), this mechanism stocks and compares OTP
contents in redundancy, see OTP memory map in annex. Recommended setting is 0xF0
(„quad“) for firmware length < 1985 bytes and 0x0F („double“) above. Quad mode simply
means triple copy of every bit and AND connection between each (note: a ccidental zero-toacam messelectronic gmbh - Friedrich-List-Str.4 - 76297 Stutensee - Germany - www.acam.de
5-15
0
�®
PCapØ1Ax-0301
one bit shift is possible, whereas one-to-zero is not). Double mode resides on a Hamming
Code parity test. Errors are corrected, as far as possible (but not repaired).
With AUTOBOOT_DIS = 0xF any automatic boot option after a power -on reset is disabled.
The chip will wait for the serial interface to write the firmware into the SRAM and to write
appropriate data to the configuration and parameter registers.
5.2.2
Comments on Register 2
Recommended settings for bits 15 through 11 are:
Table 5-1: Settings
for single capacitances connected floating
5b'01000
for single capacitances connected to ground
5b'00010
for differential capacitances connected floating
5b'10000
for differential capacitances connected to ground
5b'00010
For differential capacitors and only for them, Param7 has to be set, too. Some differential
capacitors require a mirror symmetric charge/discharge process to neutralize mechanical
stress. This option is activated through Bit 13 = ‚1‘.
Select the chip-internal discharging resistor (RDCHG_INT_SEL) as follows:
Table 5-2: Settings for parameter RDCHG_INT_SEL
Consider the largest sensor capacitance in your set-up and include stray capacitance (average 10
to 40 pF each). Also consider your reference capacitor including stray capacitance as above. Take
the largest value of all and call it C_ largest.
If C largest
5-16
< 100 pF
RDCHG_INT_SEL
= b‘100 (180 kOhm)
< 300 pF
= b‘101 (90 kOhm)
< 1 nF
= b‘110 (30 kOhm)
< 3.5 nF
= b‘111 (10 kOhm)
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�PCapØ1Ax-0301
5.2.3
Comments on Register 3
The benefit from using fake measurements depends on the individual sensors. Experiment
with different settings. With the averaging setting, begin with sample size = CMEAS_AVRG
= 1. Increasing this value gives better resolution, but lowers the measurement rate.
5.2.4
Comments on Registers 3 and 4 (timing rules)
Timing the CDC and RDC measurement depends on notions like „cycle time“ and „sequence
time“ (See chapter 3). A cycle is an elementary process; it consists of just one charging
and subsequent discharging the individual sensor paths, be it 100 µs or even several
milliseconds in extreme cases, the lower limit is 0.25 µs for the CDC part of the device. Always make sure to let sufficient time for the charging proc ess, because the discharging
is conditioned physically via the real values of capacitance and resistivity. Let as much time
for charging as for the discharging as minimum.
Too short a cycle time will lead to error conditions (time -out and port error on one or
several ports). Inadequate cycle time will increase the noise. Sometimes the capacitances
at hand are not known precisely. Especially, cable capacitances and other stray
capacitances are not known. During design and debugging, it may be wise to start w ith
large cycle times before trying to optimize this parameter down. Cycle time cannot be fixed
individually to every port; rather there is one general cycle time for the CDC and one other
for the RDC.
„Sequence Time“ is another word for „on-chip generated trigger period“. Sequence time is
not always important. It is useful when low-noise measurements must be made „from time
to time“, with some milliseconds, seconds or up to eleven minutes of idle time in between.
Saving current may be one aspect. Conversel y, the sequence-time parameter is ignored
when the chip is operated in a continuous mode where the last cycle of a preceding
measurement triggers the first cycle of the next one.
Continuous mode is commanded through CMEAS_TRIG_SEL=1 and TMEAS_TRIG_SEL=1 (o r
0 which disables the RDC). Single-conversion is always possible through op-code
commands or DSP commands. It is furthermore possible though CMEAS_TRIG_SEL=2 and
triggered through a sequence timer according to parameter SEQ_TIME (in this and only in
acam messelectronic gmbh - Friedrich-List-Str.4 - 76297 Stutensee - Germany - www.acam.de
5-17
�®
PCapØ1Ax-0301
this case this parameter counts). Third, it is possible through CMEAS_TRIG_SEL=3 and
electric pulses introduced through one of the general-purpose ports. Which one, is fixed
through parameter ..._STARTPIN.
5.2.5
Comments on Registers 4 and 5
When neither power-saving nor external synchronization is an issue, choose
CMEAS_TRIG_SEL=1 (recommended) and TMEAS_TRIG_SEL=1. TMEAS_TRIG_PREDIV=1,
maximizes the number of temperature measurements, wh ich is probably too many. With
TMEAS_TRIG_PREDIV=64, there will be one temperature measurement run for every 64
CDC measurements. Similarly the RDC trigger pre-divider divides the number of LF clock
cycles (with period approx. 20 µs) when the trigger source is chosen TMEAS_TRIG_SEL=2
(not recommended). With the TMEAS_CYTIME setting, try both possible choices. Setting
this to 1, you are on the safe side, but may lose speed.
5.2.6
Comments on Register 6
The chip device contains an internal thermo-resistance and an internal reference resistor.
Furthermore it provides three external ports for connecting thermometers/reference. All
in all, 11 combinations are supported by the chip. Standard firmware, though, as
presented here, limits to six combinations out of eleven:
Option#
Reference Resistor
External Resistor
Internal Resistor
1
Internal
None
Connected, active
2
Internal
Connected to port PT0
Connected, active
3
Internal
Connected to port PT0
Connected, inactive
4
External connected at port
PT2REF
None
Connected, active
5
External connected at port
PT2REF
Connected to port PT0
Connected, active
6
External connected at port
Connected to port PT0
Connected, inactive
5-18
acam messelectronic gmbh - Friedrich-List-Str.4 - 76297 Stutensee - Germany - www.acam.de
�PCapØ1Ax-0301
PT2REF
For any of these 6 combinations, choose parameter TMEAS_7BITS and read the results in the
output registers as follows:
Option#
TMEAS_7BITS
Contents of output registers
1
1000011 = ’h43
Res11 = R(Al_internal)/R(Si_internal)
2
1001011 = ’h4B
Res10 = R(external)/R(Si_internal)
Res11 = R(Al_internal)/R(Si_internal)
3
1001001 = ’h49
Res10 = R(external)/R(Si_internal)
4
0000110 = ’h06
Res11 = R(Al_internal)/R(Ref_external)
5
0001110 = ’h0E
Res10 = R(external)/R(Ref_external)
Res11 = R(Al_internal)/R(Ref_external)
6
0001100 = ’h0C
Res10 = R(external)/R(Ref_external)
5.2.7
Comments on Register 8
slave operation. Choose 0xA00030 for stand-alone applications. Please download
dedicated data sheet DB_PCap01_DSP_e.pdf (from www.acam.de)
The WATCHDOG parameter should be defined together with the firmware developer. When
using standard firmware (or any appropriate firmware containing “reset watchdog“
commands), the watchdog may be used and WATCHDOG_LENGTH = 3 may be a good
choice. Zero disables the watchdog.
Setting INT2PG allows the interrupt line to be outputted through the PG2 port (useful with
24-pin packages where there is no INTN pin). Using the interrupt technique is preferred to
polling the interface, because it minimizes the noise. — The low-current setting
(DSP_SPEED=3) might be incompatible with high speed measurements.
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5-19
Firmware Related
It is recommended that you use the setting 0x800030 as mentioned to get started in
�®
5.2.8
PCapØ1Ax-0301
Comments on Register 9
Further details concerning the pulse code interface should be fixed in collaboration with
the firmware deve-loper.
5.3
Read Registers
The read registers content is firmware specific, with the exception of Status. It depends
on the program that runs in the DSP. When no program is running, the result registers
will remain empty (except the status register). With the standard firmware 03.01.xx the
registers have the following content:
Address
Name
Content
Description
0
Res 0
C0 LSB
For reference only: normalized TDC value in LSB (see
note below)
1
Res 1
C1/C0
Single C: ratio C1/C0
Differential C: ratio C1/C0
2
Res 2
C2/C0 or C3/C2
Single C: ratio C2/C0
Differential C: ratio C3/C2
3
Res 3
C3/C0 or C5/C4
Single C: ratio C3/C0
Differential (only grounded) C: ratio C5/C4
4
Res 4
C4/C0 or C7/C6
Single C: ratio C4/C0
Differential (only grounded) C: ratio C7/C6
5
Res 5
C5/C0
Single C only: ratio C5/C0
6
Res 6
C6/C0
Single C only: ratio C6/C0
7
Res 7
C7/C0
Single C only: ratio C7/C0
8
Status
Status
Status information (hardwired, not firmware dependent)
11
Res 8
not used
12
Res 9
not used
13
Res 10
R0/Rref
Ratio Sensor 0 to reference
14
Res 11
R2/Rref
Ratio Sensor 2 to reference
5-20
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�PCapØ1Ax-0301
See figures 3-6 to 3-9 for a description of what C0 to C7 means. Concerning Res0, please
note that meaningful TDC values will be displayed only if C_AVRG=1 (or 0, meaning same).
Otherwise you will need to divide by the C_AVRG value. The evaluation kit performs this
without notice. After division, multiplying by the TDC bin width (typ. 22 - 25 picoseconds),
represents the discharge time encountered at C0.
Register Description in Detail:
Res1 (address 1) to Res7 (address 7):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
2
1
0
4
3
2
1
0
Cx/Cy
integer
fractional
Parameter
Description
Data range
C1/C0 etc.
Capacitance ratios. Unsigned fixed-point
numbers with 3 integer and 21 fractional
digits.
0 to 7.9999995
resolution 0.477 ppm
Status (address 8):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
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5-21
e Related
Status
�®
PCapØ1Ax-0301
Bit
Flag name
Description
23
CYC_ACTIVE
Indicates that interface communication took place during the measurement; the
measurement quality may suffer due to this; increasing the sequence time may help
22
T_END_FLAG
Indicates the end-of-temperature measurement condition; according to the settings
made, this may indicate that the device is waiting for a start command or for the
next timer-triggered start condition
20
RUNBIT
Gives back the setting of the RUNBIT in configuration register 20
16
COMBI_ERR
This is a combined condition of all known error conditions
13
CAP_ERR
Indicates an overflow or other error in the CDC.
12 to 5
CAP_ERR_PC
Indicates a port error on any CDC port (possibly too big capacitance)
3
TEMP_ERR
Indicates an overflow or other error in the RDC
Please ignore all status bits not mentioned here.
It is worthwhile mentioning that Status is the only firmware -independent read register,
both for its address as for its bit assignment. Its content will depend on sensor physics,
on front-end and on register setting, but not on the presence of the firmware or any
details. Neither will it depend on DSP operation or idleness. RUNBIT s hould generally be
present. CYC_ACTIVE may be tolerable, in continuous mode even unavoidable.
Res10 (address 13):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
R0/Rref
integer
5-22
fractional
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4
3
2
1
0
�PCapØ1Ax-0301
Parameter
Description
Data range
R0/Rref
Resitance ratios from temperature measurement.
- R0 is the external resistor connected to port PT0. - Rref might be the
external reference connected to port PT2REF or the internal Poly resistor.
0 to 7.9999995
resolution 0.477 ppm
Unsigned fixed-point numbers with 3 integer and 21 fractional digits.
Res11 (address 14):
23 22 21 20 19 18 17 16 15 14 13 12 11
10
9
8
7
6
5
4
3
2
1
0
R2/Rref
integer
fractional
Parameter
Description
Data range
R2/Rref
Resistance ratios from temperature measurement.
0 to 7.9999995
- R2 might be the external resistor connected to port PT2 or the internal
resolution 0.477 ppm
Aluminum resistor.
- Rref might be the external reference connected to port PT2REF (only with
R0 = internal Aluminum) or the internal Poly resistor.
Unsigned fixed-point numbers with 3 integer and 21 fractional digits.
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5-23
��PCapØ1Ax-0301
6
DSP, Memory & Firmware
6.1
DSP Management and Programming ........................................................ 6-2
6.2
Memory Map ....................................................................................... 6-4
6.3
Memory Management ........................................................................... 6-4
6.4
OTP Firmware programming ................................................................... 6-5
6.5
Getting Started .................................................................................... 6-6
6.5.1
SRAM Firmware programming .......................................................... 6-6
6.5.2
Configuration, Example 1 ................................................................. 6-7
6.5.3
Configuration, Example 2 ............................................................... 6-10
6.5.4
Configuration, Example 3 ............................................................... 6-12
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6-1
�®
6.1
PCapØ1Ax-0301
DSP Management and Programming
A digital signal processor (DSP) in Harvard architecture has been integrated. It is
programmable and responsible for the content of the read registers. The software, called
“firmware”, is either available ready-made from ACAM or can be user-written; Library
elements available. In the present datasheet, we describe the standard firmware 03.01.xx
as is provided by ACAM. Firmware 03.01 writes the compensated capacitance ratios and
the resistance ratios to the read registers, then performs the first -order linearization in
connection with the pulse-code outputs as described in section 4.2, but does no higher order linearization, filtering or any other data processing, though largely possible. This
Harvard DSP for 48 bit wide parallel data processing is coupled to a 48 x 48 bit RAM and
is internally clocked at approximately 100 MHz. The internal clock is stopped through a
firmware command, to save power. The DSP starts again upon a GPIO signal or an “end of
measurement run” condition.
The DSP is ACAM proprietary so as to cover low-power tasks as well as very high data
rates. It is programmed in Assembler (no high-level langu-age is available). A user-friendly
assembler software with a graphical interface, helptext pop -ups together with sample code
sustain programming efforts. Subroutines can be coded.
The DSP signals a “data ready” state to an interrupt line. The interrupt may be picked
either from the INTN port or from GPIO (PG2). Using the interrupt tech -nique has some
advantages with respect to noise and power consumption, also avoiding to produce
doublets (reading twice the same result).
6-2
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�PCapØ1Ax-0301
Figure 6-1 DSP & Memory
Doublets are likely to occur when polling the interface. If polling cannot be avoided, it may
be good practice to write incremental tags into one of the result registers, serving as a
discriminator for a doublet filter.
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6-3
�®
6.2
PCapØ1Ax-0301
Memory Map
Table 6-1 Memory organization
SRAM
OTP
Address
direct/single
dec.
hex.
4095
Length
[Byte]
Contents
Length Contents
[Byte]
Length
[Byte]
FFF
Unused
1
Test byte
1
Test byte
1
4094
..
4032
FFE
..
FC0
Config.
Registry
63
Config.
Registry
63
Config.
Registry
63
4031
FBF
..
..
2048
800h
Program
code
1984
2047
7FF
Test byte
1
2046
..
1984
7FE
..
7C0
Config.
Registry
63
1983
7BF
..
..
0
0
Program
code
1984
Program
code
Length
[Byte]
quad
Contents
6.3
Contents
double
4096
Program
code
4032
Program
code
4032
Memory Management
The DSP can be operated from SRAM (maximum speed) or from OTP (low power). When
operated from SRAM, an SRAM-to-OTP data integrity monitor can be activated through
parameter MEMCOMP in register 0, but must(!) be inactivated for operation directly from
OTP.
Memory integrity (“ECC”) mechanisms survey the OTP contents internally and correct faulty
bits (as far as possible).
Activate MEMLOCK, the memory readout blocker, through special OTP settings performed
when loading down the firmware (see the graphi-cal user interface created for firmware
development). MEMLOCK contributes to the protection of your intellectual property.
MEMLOCK gets active earliest after it was written to the OTP and the chip got a power -on
reset.
6-4
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�PCapØ1Ax-0301
6.4
OTP Firmware programming
The PCap device is equipped with a 4 kB permanent program memory spa ce, which is onetime programmable, called the OTP memory. In fact, the OTP is total 8 kB in size but 4 kB
are used for ECC mechanism. If unprogrammed -by default- an OTP byte is h‘FF, not 00.
Once programmed to 0, an OTP bit cannot be shifted back to 1. D ata retention is given for
10 years at 95°C. MEMLOCK is fourfold protected.
To program a bit in the OTP to Low or ‘0’, an external programming voltage of 6.5 V is necessary.
This voltage must be supplied to pin VPP_OTP during programming only, then removed, and pin
grounded. Hence it is impossible that an un-programmed bit be programmed to 0 spontaneously
during ordinary operation, when the VPP_OTP pin is grounded. The flowchart here shows the
sequence of steps to be performed to
program the firmware into the OTP:
It may be good practice to read the
firmware back and compare, at least
the first 960 bytes in the case of the
standard firmware. The read command
is similar to the write command with
'b001 for the leading bits:
24-bit COMMAND_READ_OTP = 'b001
+ 13-bit ADDRESS + 8-bit Firmware-byte
During the design process, if you find
some wrong bits in some of the bytes
you have read back, please (a) stop the
front end and (b) override register 0,
because the ECC_MODE parameter will
be critical for the readback process.
Useful settings are:
(a) Reg20 := 0 (runbit) and
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6-5
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PCapØ1Ax-0301
(b) Reg0 := 0
or in op-code, ‘hD4000000 and ‘hC0000000.
6.5
Getting Started
6.5.1
SRAM Firmware programming
During software development, evaluation and also in many applications the user may want
to use the SRAM as program memory, not the OTP. For this purpose, send a power -up
reset, then write the firmware into SRAM. Op-codes “Write to SRAM“ and “Read SRAM“
grant access to arbitrary SRAM addresses. The following flowchart shows the first steps
after a power on Reset.
6-6
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�PCapØ1Ax-0301
6.5.2
Configuration, Example 1
The next step after downloading the firmware is to download the configuration as
described in section 5.1.
This example refers to a basic configuration like Pcap01_standard.cfg (as it comes with
the evaluation kit).
This example features:
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6-7
�®
PCapØ1Ax-0301
Capacitance
Temperature
Timing
Single grounded capacitors,
1 sensor, 1 reference,
internally compensated,
R_disch = 30 kOhm
cycle time = 20 µs
3 Hz data rate
Averaging 100 samples
Off
Sequence-time triggered: a
chip-internal timer serves as a
trigger source, starting a CDC
sequence or run.
The configuration in detail is the following:
Register 0:
’h 42 00 FF
Register 1:
’h 20 10 22
Register 2:
’h 03 16 0B
Register 3:
’h 0D 00 64
Register 4:
’h 08 00 00
Register 5:
’h 00 00 00
Register 6:
’h 00 00 40
Register 7:
’h 1F 00 00
Register 8:
’h 80 00 30
Register 9:
’h FF 00 0F
Register 10: ’h 18 00 87
1. In order to write these 24-bit parameters, use the following 32-bit format:
{2’b11, 6’b, 24’b}
When all eleven registers are configured, finish with setting the runbit in Register
20:
{2’b11, 6’b010100, ’h000001}
2. Now the chip is ready, and measurement may begin. Send a partial reset (’h8A ),
but not a power-up reset!
3. Next, send a start command (’h8C).
4. Wait half a second, then read the status register (address 8) a nd results
(addresses 0 and 1). For reading 24-bit status and result registers, use the
following 32-bit format:
ed
6-8
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�PCapØ1Ax-0301
{2’b01, 6’b, 24’b}
It is expected to find status==’h100000 or ’h900000.
Res0 could be e.g. in the vicinity of 70000. This integer value, multiplied by 21
picoseconds (a typical time BIN size), gives an indication of the discharge time
measured. Thus, 70000 would correspond to 1.5 µs. Of course, this value depends
on the capacitances involved.
Res1 is expected to be in the range of 2,000,000 or ’h1FF2XX provided sensor
and reference are of same size. Res1 has the format of a fixed -point number with 3
integer digits and 21 fractional digits. So, dividing 2,000,000 by 2^21 gives a
result close to 1 for the ratio C1/C0.
Now, some words of caution, the 21 ps BIN size is just a typical value at room
temperature and at 3.0 volts. It will vary greatly over temperature, and it may be
batch-dependent. However, it is very constant on a sub-millisecond timescale. Given
the variability of the BIN size, we strongly recommend to make relative
measurements between some sensor and a reference; do not make absolute
measurements.
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6-9
�®
6.5.3
PCapØ1Ax-0301
Configuration, Example 2
This example refers a capacitance measurement together with a temperature
measurement (internal sensor).
This example features:
Capacitance
Temperature
Timing
Single floating capacitors
1 sensor, 1 reference, fully
compensated
R_disch = 90 kOhm
cycle time = 20 µs
12.2 Hz data rate
Averaging 100 samples
Internal sensor and reference
“end-of-C-measurement“
triggered (12.2 Hz data rate);
140 µs cycle time
Sequence time triggered as in
the example before, but at a
higher rate. Each CDC run is
triggered by the internal clock,
and the RDC run follows after
every CDC run.
The configuration in detail is the following:
Register 0:
’h 42 00 FF
Register 1:
’h 20 10 22
Register 2:
’h 0F 45 0B
Register 3:
’h 0B 00 64
Register 4:
’h 08 00 01
Register 5:
’h 00 00 00
Register 6:
’h 00 43 40
Register 7:
’h 1F 00 00
Register 8:
’h 80 00 30
Register 9:
’h FF 00 0F
Register 10: ’h 18 00 87
Steps 1 to 3 equal to those in the first example.
4. Wait 100 ms, then read the status register (address 8) and results Res0, Res1
and Res11 (addresses 0, 1 and 14). For reading 24-bit status and results use the
following 32-bit format:
{2’b01, 6’b, 24’b}
6-10
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�PCapØ1Ax-0301
It is expected to find status==‘h100000 or 0x900000.
Res0 could be e.g. in the range of 70000. This integer value, multiplied by 21 ps
(BIN size) gives an indication of the discharge time measured. With 70000 we
would have a discharge time of 1.5 µs. Of course, this value depends on the
Firmware Related
capacitors used.
Res1 is expected to be in the range of 2,000,000 or ‘h1FF2XX if the two
capacitors are of same size. Res0 has the format of a fixed point number with 3
integer digits and 21 fractional digits. So, dividing 2,000,000 by 2^21 gives a
result of about 1 for the ratio C1/C0.
Res11 gives the ratio of R(alu)/R(Si-poly) and should be something like 1,750,000.
Converted into a fractional number (division by 2^21) this is about 0.83, a typical
ratio at room temperature.
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6-11
�®
6.5.4
PCapØ1Ax-0301
Configuration, Example 3
This example refers to a capacitance measurement at 1 kHz, accompanied by infrequent
(2 Hz) temperature measurement, performed with an external sensor.
This example features:
Capacitance
Temperature
Timing
Single grounded capacitors
1 sensor, 1 reference,
internally compensated
R_disch = 30 kOhm
cycle time = 20 µs
1.04 kHz data rate
Averaging 16 samples
External PT1000 at port PT0
vs. internal Poly-Si reference
2.06 Hz data rate
280 µs cycle time
Continuous mode. The RDC is
„End of CDC“ triggered, like in
Ex. 2., but with a counter in
between, so as to bring down
the RDC rate.
The configuration in detail is the following:
Register 0:
’h 42 00 FF
Register 1:
’h 20 10 22
Register 2:
’h 03 16 0B
Register 3:
’h 06 00 10
Register 4:
’h 04 01 11
Register 5:
’h 00 01 F8
Register 6:
’h 00 49 40
Register 7:
’h 1F 00 00
Register 8:
’h 80 00 04
Register 9:
’h BB 00 00
Register 10: ’h 18 00 47
4. Wait 100 ms, then read the status register (address 8) and result register Res1
(address 1). For reading 24-bit status and result use the following 32-bit format:
{2’b01, 6’b, 24’b}
It is expected to find status==‘h100000 or ‘h900000.
6-12
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Firmware Related
Steps 1 to 3 equal those in the first example.
�PCapØ1Ax-0301
Res1 is expected to be in the range of 2,000,000 or h‘1FF2XX if the two
capacitors are of same size. Res1 has the format of a fixed point number with 3
integer digits and 21 fractional digits. So, dividing 2,000,000 by 2^21 gives a
value close to 1 for the ratio C1/C0.
Res11 gives the ratio of R(PT1000)/R(Si-poly) and should be something like
2,080,000. Converted into a fractional number (division by 2^21) this is about
0.992, a typical ratio at room temperature.
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6-13
��PCapØ1Ax-0301
7
Miscellaneous
7.1
Bug Report ......................................................................................... 7-2
7.1.1
I2C Bug ........................................................................................ 7-2
7.1.2
Spikes on IIC Interface ..................................................................... 7-3
7.1.3
SPI Limitation ................................................................................ 7-4
7.1.4
Power-up Reset Limitation ................................................................ 7-4
7.2
Document History ................................................................................ 7-6
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7-1
�®
7.1
Bug Report
7.1.1
I2C Bug
PCapØ1Ax-0301
Description
In case PCap01A is not the only device on the I2C bus, we have the following errors:
Table 7-1: Communication between Master and some Slave other than PCap01
Situation
Expected behavior
Actual behavior
Conclusio
n
Master initializes
communication with
another slave than
PCap01
PCap01 should remain
silent like it were
absent from the bus.
PCap01 acknowledges any
address byte. It sets the ACK
bit like if it had been called
with its own address (1)(2)
wrong
Master has estab-lished
commu-ni-ca-tion with
another slave and is
writing data to, or reading
data from it.
PCap01 should remain
neatly off the SDA line.
PCap01 acknowledges any
data byte in parallel to
slave's(2) and master's(3)
ACK or despite their
respective NACK
wrong
PCap01 should ignore
the data bits
themselves
PCap01 does not listen to
those data bits that are sent
to others.
right
(1) If the requested slave is present and ready to respond, this will be tolerable.
(2) NACK (refused acknowledge) no longer exists in this kind of a situation.
(3) This kind of “meddling with the master‘s business“ may trouble the master (caution with
integrated i2C controllers). Master is requested not to leave its master status, but to remain
master and to issue a STOP condition.
Preliminary suggestions
Take the SPI interface, if possible. No problem detected on SPI.
If you need the I2C interface, restructure your network so that PCap01 is
connected single-slave to the master.
If you need I2C and cannot avoid a multi-slave bus structure, be aware of the
restrictions to the bus protocol, described in this report
7-2
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�PCapØ1Ax-0301
Consequences on integrated I2C controllers (with more than one slave)
The use of hardwired I2C interfaces with multi-master capability may cause error during
read operations, because a master may go to Error due to some ACK bit arriving within a
„read“ process (as the master alone should acknowledge data from slaves). This m ay
completely block the interface, unless the master has been instructed not to listen to the
line for detecting possible master-collision situations.
(Remark “master-collision situations“: In multi-master systems, two members may
incidentally become co-masters. This is part of the standard. Both co-masters listen to the
SDA line and become slave as soon as they detect a collision. This is what PCap01
provokes; all masters become slave, and the bus hangs. )
As write operations are possible, I2C expanders may be used to interface PCap01 in multislave systems.
Consequences on hand-written, „software“ I2C interfaces
You are recommended to simplify and to modify the interface protocol:
The most basic subset of the I2C standard will be best.
Multi-master, arbitration and the like should be skipped.
Master must ignore any ACK bits set in competition with its own ACKs or NACKs.
Master cannot rely on any ACK bits issued by other slaves than PCap01. ACK bits
are likely to come from PCap01. Pay attention to this, especially during debugging
and for error-handling.
Some work-around may be necessary in order to check for the presence and
readiness of a slave, which standardwise would be signaled through an ACK.
You cannot use NACK bits. In particular, NACK cannot be used to signal “end of
transfer“ to a slave. You must abort by a repeated-start or by a stop condition.
7.1.2
If possible, use an I2C expander in multi-slave applications.
Spikes on IIC Interface
It was observed that spikes on the IIC lines, especially SDA to SCL crosstalk is causing a
bit stream of ones („1”). This way, it appears in the data like a „freezing“ of values, e.g.
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7-3
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PCapØ1Ax-0301
the temperature value. The background of this error is that the spike is seen by PCap01
as an acknowledge bit (ACK) and therefore active sending is stopped. The master still
sends clock cycles and by means of the pull-up a series of „1“ is generated.
The error occurs usually when a typical bit pattern is proceeding, which is XXXX_0001 or
XXXX_0101. The following byte is then 1111_1111.
Workaround: the spike should be filtered at the inputs of PCap01. This can be achieved in
two ways:
1.) Insert a small capacitance, e.g. 10 pF from SCL line to either GND or VDD. It should
be placed close to the chip.
2.) Insert a series resistor of 100 Ohms in the SDA line. Again, place it close to the chip.
7.1.3
SPI Limitation
In some applications, several components are wired to the same SPI bus and are
individually ad-dressed through the chip-select (SSN) line. For this to work, any nonaddressed component, seeing SSN ‘high‘, must set its MISO port to high impedance. No
high-impedance state existing on MISO port inside PCap01.
Workaround: Avoid sharing MISO, or insert an (inexpensive) external single -gate tri-state
buffer between PCap‘s MISO port and the MISO line.
7.1.4
Power-up Reset Limitation
In case of shorttime power down, the PCap01 does not safely detect the power -down
status. In consequence, it may happen that the chip does not run a power -up procedure
but hangs.
Workaround: a) Operated as a slave, upon power-down, the PCap01A needs a dedicated
software power-up reset via the interface by the microcontroller.
b) Operated stand-alone, the PCap01A may need an additional external power -up circuit.
However, if power consumption is not critical, a simple 11 kOhm resistor between
7-4
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�PCapØ1Ax-0301
BUFFCAP and GROUND is believed to be sufficient as a workaround, for any power
shutdown lasting 100 ms or more.
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7-5
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7.2
PCapØ1Ax-0301
Document History
04.08.2010 First release
11.04.2012 Two dozen minor corrections and amendments, throughout the chapters;
separation between hardware and software aspects (blue stripe in margin)
16.01.2013 Corrections and amendments in the chapters 2, 5 and 7
15.07.2013 version 0.6 released with following changes:
- in register 2, parameter C_GRD_FLOAT replaced by CMEAS_SCHEME
- supplement in the read register overview in chapter 5.3
- calculation of CMEAS_CYTIME fixed.
7-6
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