TI TSC2100IDA

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SLAS378− NOVEMBER 2003
FEATURES
DESCRIPTION
D Integrated Touch Screen Processor With
The TSC2100 is a highly integrated touch screen
controller with on-chip processor and audio codec. The
touch screen portion of the TSC2100 contains a 12-bit
4-wire resistive touch screen ADC complete with drivers,
and interfaces to the host controller through a standard
SPI serial interface. The on-chip processor provides
extensive features specifically designed to reduce host
processor and bus overhead, with capabilities that include
fully automated operating modes, programmable
conversion resolution up to 12 bits, programmable
sampling rates up to 125 kHz, programmable conversion
averaging, and programmable on-chip timing generation.
Fully Automated Modes of Operation
D Programmable Converter Resolution, Speed,
and Averaging
D Programmable Autonomous Timing Control
D Direct Battery Measurement Accepts up to
6-V Input
D On-Chip Temperature Measurement
D Stereo Audio DAC and Mono Audio ADC
Support Rates up to 48 ksps
D High Quality 97-dB Stereo Audio
D Integrated PLL for Flexible Audio Clock
Generation
D Programmable Digital Audio
Bass/Treble/EQ/De-Emphasis
D On-Chip 325-mW, 8- Speaker Driver
D Stereo Headphone Amplifier With Capless
Output Option
D Microphone Preamp and Hardware Automatic
Gain Control
D SPI and I2S Serial Interface
D Full Power-Down Control
D Low Power: 11-mW Stereo Audio Playback At
48 ksps
D 32-Pin TSSOP and 32-Pin 5y5 mm QFN
Package
APPLICATIONS
D Personal Digital Assistants
D Smart Cellular Phones
D MP3 Players
The TSC2100 includes a high-performance audio codec
with 16/20/24/32-bit 97-dB stereo playback, mono record
functionality at up to 48 ksps. A microphone input includes
built-in preamp and hardware automatic gain control, with
single-ended or fully-differential input capability. The dual
output drivers on the TSC2100 can be programmed for low
or high power drive for optimized power saving capability.
The drivers can function as a stereo line-level output, a
stereo headphone amplifier with capless or ac-coupled
configurations, or a bridge-terminated speaker driver,
delivering up to 325 mW into an 8-Ω load. A programmable
digital audio effects processor enables bass, treble,
midrange, or equalization playback processing. The digital
audio data format is programmable to work with popular
audio standard protocols (I2S, DSP, Left/Right Justified) in
master or slave mode, and also includes an on-chip
programmable PLL for flexible clock generation capability.
Highly configurable software power control is provided,
enabling stereo audio playback at 48 ksps at 11 mW with
a 3.3-V analog supply level.
The TSC2100 offers a 12-bit measurement ADC and
internal reference voltage, as well as two battery
measurement inputs capable of reading battery voltages
up to 6 V, while operating at an analog supply as low as
2.7 V. It includes an on-chip temperature sensor capable
of reading 0.3°C resolution. The TSC2100 is available in
a 32 lead TSSOP and a 32 lead QFN.
US Patent No. 624639
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments
semiconductor products and disclaimers thereto appears at the end of this data sheet.
SPI is a trademark of Motorola.
I2S is a trademark of Phillips Electronics.
! " #$%! " &$'(#! )!%* )$#!"
# ! "&%##!" &% !+% !%" %," "!$%!" "!)) -!.*
)$#! &#%""/ )%" ! %#%""(. #($)% !%"!/ (( &%!%"*
Copyright  2003, Texas Instruments Incorporated
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SLAS378− NOVEMBER 2003
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate
precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to
damage because very small parametric changes could cause the device not to meet its published specifications.
PACKAGE/ORDERING INFORMATION
PRODUCT
PACKAGE
PACKAGE DESIGNATOR
TSSOP-32
DA
QFN-32
RHB
OPERATING
TEMPERATURE RANGE
TSC2100IDA
TRANSPORT MEDIA,
QUANTITY
ORDERING NUMBER
−40°C to 85°C
TSC2100IDA
Tubes, 46
TSC2100IDAR
Tape and Reel, 2000
TSC2100IRHB
Tubes, 52
TSC2100IRHBR
Tape and Reel, 3000
PIN ASSIGNMENTS
1
32
2
31
3
30
4
29
5
28
6
27
7
26
8
25
9
24
10
23
11
22
12
21
13
20
14
19
15
18
16
17
(TOP VIEW)
PWD/ADWS
LRCK
RESET
HPR
DRVDD
VGND
DRVSS
HPL
AVDD
X+
Y+
X−
Y−
AVSS
VREF
VBAT1
DVSS
IOVDD
MCLK
SCLK
MISO
MOSI
SS
PINTDAV
QFN
DVDD
BCLK
DOUT
DIN
PWD/ADWS
LRCK
RESET
HPR
DIN
DOUT
BCLK
DVDD
DVSS
IOVDD
MCLK
SCLK
MISO
MOSI
SS
PINTDAV
MICBIAS
MICIN
AUX
VBAT2
TSSOP
32 31 30 29 28 27 26 25
1
24
2
23
22
3
21
20
4
5
7
19
18
8
17
6
DRVDD
VGND
DRVSS
HPL
AVDD
X+
Y+
X−
9 10 11 12 13 14 15 16
MICBIAS
MICIN
AUX
VBAT2
VBAT1
VREF
AVSS
Y−
(TOP VIEW)
Terminal Functions
2
QFN
PIN
TSSOP
PIN
QFN
PIN
TSSOP
PIN
NAME
29
1
DIN
30
2
DOUT
Audio data input
13
17
VBAT1
Battery monitor input
Audio data output
14
18
VREF
31
3
Reference voltage I/O
BCLK
Audio bit−clock
15
19
AVSS
32
4
Analog ground
DVDD
Digital core supply
16
20
Y−
Y− position input and driver
1
2
5
DVSS
Digital core and IO ground
17
21
X−
X− position input and driver
6
IOVDD
IO supply
18
22
Y+
Y+ position input and driver
3
7
MCLK
Master clock
19
23
X+
X+ position input and driver
4
8
SCLK
SPI serial clock input
20
24
AVDD
5
9
MISO
SPI serial data output
21
25
HPL
6
10
MOSI
SPI serial data input
22
26
DRVSS
Speaker ground
7
11
SS
SPI slave select input
23
27
VGND
Virtual ground for audio output
8
12
PINTDAV
Pen interrupt/data available output
24
28
DRVDD
9
13
MICBIAS
Microphone bias voltage
25
29
HPR
10
14
MICIN
Microphone input
26
30
RESET
11
15
AUX
Auxiliary input
27
31
LRCK
12
16
VBAT2
Battery monitor input
28
32
PWD/ADWS
NAME
DESCRIPTION
DESCRIPTION
Analog power supply
Left channel audio output
Speaker /PLL supply
Right channel audio output
Device reset
Audio DAC word-clock
Hardware powerdown/ADC word clock
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SLAS378− NOVEMBER 2003
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range unless otherwise noted(1)(2)(3)
UNITS
AVDD to AVSS
−0.3 V to 3.9 V
DRVDD to DRVSS
−0.3 V to 3.9 V
IOVDD to DVSS
−0.3 V to 3.9 V
DVDD to DVSS
−0.3 V to 2.5 V
AVDD to DRVDD
−0.1 V to 0.1 V
AVSS to DRVSS to DVSS
−0.1 V to 0.1 V
Analog inputs (except VBAT1 and VBAT2) to AVSS
VBAT1 / VBAT2 to AVSS
−0.3 V to AVDD + 0.3 V
−0.3 V to 6 V
Digital input voltage to DVSS
−0.3 V to IOVDD + 0.3 V
Operating temperature range
−40°C to 85°C
Storage temperature range
−65°C to 105°C
Junction temperature (TJ Max)
Power dissipation
TSSOP package
θJA Thermal impedance
Power dissipation
QFN package
θJA Thermal impedance
Soldering vapor phase (60 sec)
Lead temperature
Infrared (15 sec)
105°C
(TJ Max − TA)/θJA
86°C/W
(TJ Max − TA)/θJA
123°C/W
215°C
220°C
(1) Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not
implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) If the TSC2100 QFN version is used to drive high power levels to an 8-Ω load for extended intervals at ambient temperatures above 70°C, multiple
vias should be used to electrically and thermally connect the thermal pad on the QFN package to an internal heat-dissipating ground plane on the
user’s PCB.
(3) The TSC2100 TSSOP version provides full output power into an 8-Ω load at ambient temperatures of 70°C and below. TI does not recommend
using the TSC2100 TSSOP version to drive high power levels to an 8-Ω load for extended intervals at ambient temperatures above 70°C. All other
device functionality, including driving of stereo 16-Ω loads at full volume, is supported up to 85°C.
3
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SLAS378− NOVEMBER 2003
ELECTRICAL CHARACTERISTICS
At +25°C, AVDD,DRVDD,IOVDD = 3.3 V, DVDD = 1.8 V, Int. Vref = 2.5 V, Fs (Audio) = 48 kHz, unless otherwise noted
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
TOUCH SCREEN
AUXILIARY ANALOG INPUT
Input voltage range
0
Input capacitance
AUX selected as input to touch screen ADC
Input leakage current
+VREF
V
25
pF
±1
µA
BATTERY MONITOR INPUTS
Input voltage range
0.5
Input leakage current
6.0
±1
Battery conversion not selected
V
µA
TOUCH SCREEN A/D CONVERTER
Resolution
Programmable: 8-, 10-,12-bits
No missing codes
12-bit resolution
12
11
Bits
Bits
Integral nonlinearity
−5
5
LSB
Offset error
−6
6
LSB
−6
6
LSB
Calculated with effect of internal reference
variation removed.
Gain error
Noise
µVrms
53
AUDIO CODEC
ADC DECIMATION FILTER
Sample rate of 48 ksps
Filter gain from 0 to 0.39Fs
Filter gain at 0.4125Fs
Filter gain at 0.45Fs
Filter gain at 0.5Fs
Filter gain from 0.55Fs to 64Fs
Filter group delay
±0.1
dB
−0.25
dB
−3
dB
−17.5
dB
−75
dB
17/Fs
Sec
MICROPHONE INPUT TO ADC
1 kHz sine wave input, Fs = 48 ksps
Full scale input voltage (0 dB)
By design, not tested in production
0.707
Vrms
Input common mode
By design, not tested in production
1.35
V
SNR
Measured as idle channel noise, 0-dB gain,
A-weighted
THD
0.63-Vrms input, 0-dB gain
PSRR
1 kHz, 100 mVpp on AVDD.(1)
Mute attenuation
Output code with 0.63-Vrms sine wave input at
1 kHz
80
92
−89
57
dBA
−72
dB
dB
0000H
Input resistance
20
kΩ
Input capacitance
10
pF
D4 = 0 control register 05H/Page2
2.5
V
D4 = 1 control register 05H/Page2
2.0
V
4.7
mA
MICROPHONE BIAS
Voltage
Sourcing current
(1) ADC PSRR measurement is calculated as:
ǒ
PSRR + 20 log 10
4
VSIG sup
V
Ǔ
ADCOUT
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SLAS378− NOVEMBER 2003
ELECTRICAL CHARACTERISTICS
At +25°C, AVDD,DRVDD,IOVDD = 3.3 V, DVDD = 1.8 V, Int. Vref = 2.5 V, Fs (Audio) = 48 kHz, unless otherwise noted (continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
DAC INTERPOLATION FILTER
Pass band
20
0.45Fs
±0.06
Pass band ripple
Transition band
Stop band
Hz
dB
0.45Fs
0.5501Fs
Hz
0.5501Fs
7.455Fs
Hz
Stop band attenuation
Filter group delay
De−emphasis error
65
dB
21/Fs
Sec
±0.1
dB
1-kHz sine wave input, 48 ksps, output drivers
in low power mode, load = 10 kΩ, 10 pF
DAC LINE OUTPUT
Full scale output voltage (0 dB)
By design, D10−D9 = 00 in control register
06H/Page2 corresponding to 2-VPP output
swing
0.707
Vrms
Output common mode
By design, D10−D9 = 00 in control register
06H/Page2 corresponding to 2-VPP output
swing
1.35
V
SNR
Measured as idle channel noise, A-weighted
THD
0-dB FS input, 0-dB gain
PSRR
85
97
dBA
−95
dB
1 kHz, 100mVpp on AVDD(2) VGND powered
down
56
dB
Interchannel isolation
Coupling from ADC to DAC
84
dB
DAC HEADPHONE OUTPUT
1-kHz sine wave input, 48 ksps, output drivers
in high power mode, load = 16 Ω, 10 pF
Full scale output voltage (0 dB)
By design, D10−D9 = 00 in control register
06H/Page2 corresponding to 2-VPP output
swing
SNR
Measured as idle channel noise, A-weighted
THD
−1 dBFS input, 0-dB gain
PSRR
1 kHz, 100 mVpp on AVDD(1) VGND powered
down
Interchannel isolation
Coupling from ADC to DAC
85
D10−D9 = 00 in control register 06H/Page2
Digital volume control gain
Vrms
97
dBA
−91
Mute attenuation
Maximum output power
0.707
dB
dB
85
dB
121
dB
30
−63.5
Digital volume control step size
−55
54
mW
0
dB
0.5
dB
80
dB
Channel separation
Between HPL and HPR
DAC SPEAKER OUTPUT
Output driver in high power mode,
load = 8 Ω,, connected between HPR and HPL
pins. D10−D9 = 10 in control register
06H/Page2 corresponding to 2.402-VPP output
swing
Output power
0 dB input to DAC
325
mW
SNR
Measured as idle channel noise, A-weighted
102
dBA
THD
0 dBFS input, 0-dB gain
−33
dB
−6 dBFS input, 0-dB gain
−88
dB
(1) DAC PSRR measurement is calculated as:
ǒ
PSRR + 20 log 10
Ǔ
VSIG sup
V
HPRńL
5
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SLAS378− NOVEMBER 2003
ELECTRICAL CHARACTERISTICS
At +25°C, AVDD,DRVDD,IOVDD = 3.3 V, DVDD = 1.8 V, Int. Vref = 2.5 V, Fs (Audio) = 48 kHz, unless otherwise noted (continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
VOLTAGE REFERENCE
Voltage range
VREF output programmed as 2.5 V
2.3
2.5
2.7
VREF output programmed as 1.25 V
1.15
1.25
1.35
Voltage range
External VREF. By design, not tested in
production.
Reference drift
Internal VREF = 1.25 V
Current drain
Extra current drawn when the internal
reference is turned on.
1.2
2.55
V
V
29
ppm/°C
650
µA
8.8
MHz
DIGITAL INPUT / OUTPUT(1)
Internal clock frequency
Logic family
CMOS
Logic level:
VIH
VIL
VOH
VOL
Capacitive load
IIH = +5 µA
IIL = +5 µA
0.7xIOVDD
IOH = 2 TTL loads
IOL = 2 TTL loads
0.8xIOVDD
V
−0.3
0.3xIOVDD
V
V
0.1xIOVDD
10
V
pF
POWER SUPPLY REQUIREMENTS
Power supply voltage
AVDD(2)
2.7
3.6
DRVDD(2)
2.7
3.6
V
IOVDD
1.1
3.6
V
1.95
V
DVDD
1.525
IAVDD
Touch-screen ADC quiescent current
IDRVDD
IDVDD
IAVDD
Stereo audio playback
IDRVDD
IDVDD
Host controlled AUX
conversion at
10 ksps with external
reference.
47
48 ksps, output drivers in low
power mode, VGND off, PLL
off
2.2
IAVDD
Microphone record
IDRVDD
48 ksps, no playback, PLL off
IDVDD
0
mA
1.3
mA
0.9
IAVDD
IDRVDD
mA
2.4
0.1
Additional power consumed
when PLL is enabled.
IDVDD
VGND
0
1.4
IAVDD
PLL
µA
65
2.9
IDVDD
IDRVDD
0
V
0.3
Additional power consumed
when VGND is powered.
0.9
mA
0
Hardware power down
All currents
2
µA
(1) Internal oscillator is designed to give nominally 8-MHz clock frequency. However, due to process variations, this frequency can vary from device
to device. All calculations for delays and wait times in the data sheet assume an 8-MHz oscillator clock.
(2) It is recommended that AVDD and DRVDD be set to the same voltage for the best performance. It is also recommended that these supplies be
separated on the user’s PCB.
6
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SLAS378− NOVEMBER 2003
FUNCTIONAL BLOCK DIAGRAM
DRVDD
DRVSS
AVDD
AVSS
DVDD
DVSS
0 to −63.5 dB
(0.5 dB Steps)
High Power Driver
HPR
IOVDD
Σ
∑−∆
DAC
Σ
∑−∆
DAC
Σ
Vol
Ctl
Σ
Vol
Ctl
PLL
MCLK
PWD/ADWS
High Power Driver
HPL
VGND
DAC CM
MICBIAS
2.5 V/2 V
Analog Volume
Control −34.5 to
12 dB
Sidetone
−48 to 0 dB
1.5 dB Steps
DOUT
LRCK
Digital
Audio
Processing
and Serial
Interface
DIN
BCLK
0 to 59.5 dB
(0.5 dB Steps)
MICIN
∑−∆
ADC
AGC
AUX
X+
Y+
X−
Y−
RESET
Touch
Panel
Drivers
VBAT1
Battery
Monitor
VBAT2
Battery
Monitor
Touch
Screen
Processing
and SPI
Interface
∑−∆
ADC
SCLK
SS
MOSI
MISO
PINTDAV
Temperature
Measurement
VREF
Internal 2.5 V/
1.25 V
Reference
OSC
7
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SLAS378− NOVEMBER 2003
SPI TIMING DIAGRAM
SS
t
t
t Lead
t Lag
td
s ck
SCLK
t wsck
tf
tr
t wsck
tv
MISO
t ho
MSB OUT
t dis
BIT . . . 1
LSB OUT
ta
MOSI
t hi
t su
MSB OUT
BIT . . . 1
LSB OUT
TYPICAL TIMING REQUIREMENTS
All specifications at 25°C, DVDD = 1.8 V (1)
IOVDD = 1.1 V
PARAMETER
MIN
MAX
IOVDD = 3.3 V
MIN
MAX
UNITS
twsck
tLead
SCLK pulse width
27
18
ns
Enable lead time
18
15
ns
tLag
ttd
Enable lag time
18
15
ns
Sequential transfer delay
18
ta
tdis
Slave MISO access time
tsu
thi
MOSI data setup time
6
6
ns
MOSI data hold time
6
6
ns
tho
tv
MISO data hold time
4
Slave MISO disable time
MISO data valid time
tr
Rise time
tf
Fall time
(1) These parameters are based on characterization and are not tested in production.
8
15
18
18
ns
15
ns
15
ns
4
ns
22
13
ns
6
4
ns
6
4
ns
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SLAS378− NOVEMBER 2003
AUDIO INTERFACE TIMING DIAGRAMS
LRCK/ADWS
td (WS)
BCLK
td (DO−WS)
td (DO−BCLK)
DOUT
ts (DI)
th (DI)
DIN
Figure 1. I2S/LJF/RJF Timing in Master Mode
TYPICAL TIMING REQUIREMENTS (FIGURE 1)
All specifications at 25°C, DVDD = 1.8 V (1)
IOVDD = 1.1 V
PARAMETER
MIN
MAX
IOVDD = 3.3 V
MIN
MAX
UNITS
td (WS)
td (DO−WS)
ADWS/LRCK delay
25
15
ns
ADWS to DOUT delay (for LJF mode)
25
15
ns
td (DO−BCLK)
ts(DI)
BCLK to DOUT delay
25
15
ns
DIN setup
6
6
th(DI)
tr
DIN hold
6
6
Rise time
tf
Fall time
(1) These parameters are based on characterization and are not tested in production.
ns
ns
10
6
ns
10
6
ns
LRCK/ADWS
td (WS)
td (WS)
BCLK
td (DO−BCLK)
DOUT
th (DI)
ts (DI)
DIN
Figure 2. DSP Timing in Master Mode
TYPICAL TIMING REQUIREMENTS (FIGURE 2)
All specifications at 25°C, DVDD = 1.8 V(1)
IOVDD = 1.1 V
PARAMETER
MIN
MAX
IOVDD = 3.3 V
MIN
MAX
UNITS
td (WS)
td (DO−BCLK)
ADWS/LRCK delay
25
15
ns
BCLK to DOUT delay
25
15
ns
ts(DI)
th(DI)
DIN setup
6
6
ns
DIN hold
6
6
ns
tr
Rise time
tf
Fall time
(1) These parameters are based on characterization and are not tested in production.
10
6
ns
10
6
ns
9
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SLAS378− NOVEMBER 2003
LRCK/ADWS
th (WS)
BCLK
tL(BCLK)
tS (WS)
tH(BCLK)
td(DO−WS)
tP(BCLK)
td(DO−BCLK)
DOUT
th (DI)
ts (DI)
DIN
Figure 3. I2S/LJF/RJF Timing in Slave Mode
TYPICAL TIMING REQUIREMENTS (FIGURE 3)
All specifications at 25°C, DVDD = 1.8 V (1)
IOVDD = 1.1 V
PARAMETER
MIN
MAX
IOVDD = 3.3 V
MIN
MAX
UNITS
tH (BCLK)
tL (BCLK)
BCLK high period
35
35
ns
BCLK low period
35
35
ns
ts(WS)
th(WS)
ADWS/LRCK setup
6
6
ns
ADWS/LRCK hold
6
td (DO−WS)
td (DO−BCLK)
ADWS to DOUT delay (for LJF mode)
25
18
ns
BCLK to DOUT delay
25
15
ns
ts(DI)
th(DI)
DIN setup
6
6
ns
DIN hold
6
6
ns
tr
Rise time
tf
Fall time
(1) These parameters are based on characterization and are not tested in production.
10
6
ns
5
4
ns
5
4
ns
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SLAS378− NOVEMBER 2003
LRCK/ADWS
tS (WS)
tH(BCLK)
th(WS)
th(WS)
tS (WS)
tL(BCLK)
BCLK
td(DO−BCLK)
tP(BCLK)
DOUT
th (DI)
ts (DI)
DIN
Figure 4. DSP Timing in Slave Mode
TYPICAL TIMING REQUIREMENTS (FIGURE 4)
All specifications at 25°C, DVDD = 1.8 V (1)
IOVDD = 1.1 V
PARAMETER
MIN
MAX
IOVDD = 3.3 V
MIN
MAX
UNITS
tH (BCLK)
tL (BCLK)
BCLK high period
35
35
ns
BCLK low period
35
35
ns
ts(WS)
th(WS)
ADWS/LRCK setup
6
6
ns
ADWS/LRCK hold
6
6
ns
td (DO−BCLK)
ts(DI)
BCLK to DOUT delay
DIN setup
6
6
ns
th(DI)
tr
DIN hold
6
6
ns
Rise time
tf
Fall time
(1) These parameters are based on characterization and are not tested in production.
25
15
ns
5
4
ns
5
4
ns
11
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SLAS378− NOVEMBER 2003
TYPICAL CHARACTERISTICS
1.5
1
LSB
0.5
0
−0.5
−1
−1.5
0
500
1000
1500
2000
CODE
2500
3000
3500
4000
Figure 5. SAR INL (TA = 25°C, Internal Ref = 2.5 V, 12 bit, AVDD = 3.3 V)
1
LSB
0.5
0
s
−0.5
−1
0
500
1000
1500
2000
CODE
2500
3000
3500
4000
Figure 6. SAR DNL (TA = 25°C, Internal Ref = 2.5 V, AVDD = 3.3 V)
1.8
1.6
1.4
Power − mW
1.2
1
0.8
0.6
0.4
0.2
0
0
20
40
60
80
Sampling Rate − ksps
Figure 7. Touch Screen Power Consumption With Speed (TA = 25°C, External Ref, Host Controlled AUX
Conversion, AVDD = 3.3 V)
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0
−20
−40
dB
−60
−80
−100
−120
−140
−160
0
500
1000
1500
2000
2500
3000
3500
4000
Hz
Figure 8. ADC FFT Plot at 8 ksps (TA = 25°C, −1 dB, 1 kHz Input, AVDD = 3.3 V)
0
−20
−40
dB
−60
−80
−100
−120
−140
−160
0
5000
10000
15000
20000
Hz
Figure 9. ADC FFT Plot at 48 ksps (TA = 25°C, −1 dB, 1 kHz Input, AVDD = 3.3 V)
90
89.5
Dynamic Range − dB
89
88.5
88
87.5
87
86.5
86
8
18
28
38
Sampling Rate − ksps
48
Figure 10. ADC Dynamic Range vs Sampling Speed (TA = 25°C, AVDD = 3.3 V)
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0
−20
−40
dB
−60
−80
−100
−120
−140
−160
0
5000
10000
15000
20000
Hz
Figure 11. DAC FFT Plot (TA = 25°C, 48 ksps, 0 dB, 1 kHz Input, AVDD = 3.3 V, RL = 10 kΩ)
0
−10
−30
dB
−50
−70
−90
−110
−130
−150
0
5000
10000
Hz
15000
20000
Figure 12. DAC FFT Plot (TA = 25°C, 48 ksps, −1 dB, 1 kHz Input, AVDD = DRVDD = 3.3 V, DVDD = 1.8 V,
RL = 16 Ω)
THD − Total Harmonic Distortion − dB
−88
−90
−92
−94
5
15
25
35
Output Power − mW
Figure 13. High Power Output Driver THD vs Output Power
(TA =25°C, AVDD, DRVDD = 3.3 V, RL = 16 )
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OVERVIEW
The TSC2100 is a highly integrated touch screen controller with stereo audio codec for portable computing,
communication, and entertainment applications. A register-based architecture eases integration with
microprocessor-based systems through a standard SPI bus. All peripheral functions are controlled through the registers
and onboard state machines.
The TSC2100 consists of the following blocks (refer to the block diagram):
D
D
D
D
D
Touch Screen Interface
Battery Monitors
Auxiliary Inputs
Temperature Monitor
Audio Codec
Communication to the TSC2100 is via a standard SPI serial interface. This interface requires that the slave select signal
be driven low to communicate with the TSC2100. Data is then shifted into or out of the TSC2100 under control of the host
microprocessor, which also provides the serial data clock.
Control of the TSC2100 and its functions is accomplished by writing to different registers in the TSC2100. A simple
command protocol is used to address the 16−bit registers. Registers control the operation of the A/D converter and audio
codec.
A typical application of the TSC2100 is shown in Figure 14.
12S Interface
Auxilary Input
AUX
MCLK
X+
Y+
X−
Touch Screen
Y−
Audio
2.2 k
8
Speaker
ADC Word Select
LRCK
DAC Word Select
DIN
MICBIAS
MICIN
BCLK
R1
V1: Main Battery
V2: Secondary Battery
C1: 1 µF − 10 µF (Optional)
C2: 0.1 µF
C3, C4: 0.1 F,
R1, R2: 200 − 300 V1
V2
C3
PINTDAV
VBAT1
VBAT2
R2
C4
C1
Serial Input From CPU/DSP
Serial Clock Input
Pen Interrupt Request to CPU
MISO
Serial Output to SPI Master
MOSI
Serial Input From SPI Master
SS
SPI Slave Select Input
SCLK
SPI Serial Clock Input
VREF
C2
Serial Output to CPU/DSP
SPI Interface
HPR
HPL
VGND
Master Clock Input
ADWS/
PWDZ
DOUT
Figure 14. Typical Circuit Configuration
OPERATION—TOUCH SCREEN
A resistive touch screen works by applying a voltage across a resistor network and measuring the change in resistance
at a given point on the matrix where a screen is touched by an input stylus, pen, or finger. The change in the resistance
ratio marks the location on the touch screen.
The TSC2100 supports the resistive 4-wire configurations (see Figure 14). The circuit determines location in two coordinate
pair dimensions, although a third dimension can be added for measuring pressure.
The 4-Wire Touch Screen Coordinate Pair Measurement
A 4-wire touch screen is constructed as shown in Figure 15. It consists of two transparent resistive layers separated by
insulating spacers.
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Conductive Bar
Transparent Conductor (ITO)
Bottom Side
Y+
X+
Transparent Conductor (ITO)
Top Side
X−
Silver Ink
Y−
Insulating Material (Glass)
ITO= Indium Tin Oxide
Figure 15. 4-Wire Touch Screen Construction
The 4-wire touch screen panel works by applying a voltage across the vertical or horizontal resistive network. The A/D
converts the voltage measured at the point the panel is touched. A measurement of the Y position of the pointing device
is made by connecting the X+ input to a A/D converter, turning on the Y drivers, and digitizing the voltage seen at the X+
input. The voltage measured is determined by the voltage divider developed at the point of touch. For this measurement,
the horizontal panel resistance in the X+ lead does not affect the conversion due to the high input impedance of the A/D
converter.
Voltage is then applied to the other axis, and the A/D converts the voltage representing the X position on the screen. This
provides the X and Y coordinates to the associated processor.
Measuring touch pressure (Z) can also be done with the TSC2100. To determine pen or finger touch, the pressure of the
touch needs to be determined. Generally, it is not necessary to have very high performance for this function; therefore, the
8-bit resolution mode is recommended (however, calculations are shown with the 12-bit resolution mode). There are
several different ways of performing this measurement. The TSC2100 supports two methods. The first method requires
knowing the X-plate resistance, measurement of the X-Position, and two additional cross panel measurements (Z2 and Z1)
of the touch screen (see Figure 16). Using equation 1 calculates the touch resistance:
R
TOUCH
+R
X–plate
ǒ Ǔ
X–position Z 2
–1
4096
Z1
(1)
The second method requires knowing both the X-plate and Y-plate resistance, measurement of X-Position and Y-Position,
and Z1. Using equation 2 also calculates the touch resistance:
R
R
TOUCH
+
ǒ
Measure X-Position
Y+
X+
Ǔ
X−position
X−plate
4096 * 1
4096
Z1
*R
ǒ1* Y−position
Ǔ
4096
Measure Z1-Position
X+
Y+
X-Position
Z1-Position
i
Y−
X−
X+
(2)
Y+
Touch
Touch
Touch
X−
Y−plate
Y−
Z2-Position
X−
Y−
Measure Z2-Position
Figure 16. Pressure Measurement
When the touch panel is pressed or touched, and the drivers to the panel are turned on, the voltage across the touch panel
often overshoots and then slowly settles (decays) to a stable dc value. This is due to mechanical bouncing which is caused
by vibration of the top layer sheet of the touch panel when the panel is pressed. This settling time must be accounted for,
or else the converted value is in error. Therefore, a delay must be introduced between the time the driver for a particular
measurement is turned on, and the time measurement is made.
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In some applications, external capacitors may be required across the touch screen for filtering noise picked up by the touch
screen, i.e. noise generated by the LCD panel or back-light circuitry. The value of these capacitors provides a low-pass
filter to reduce the noise, but causes an additional settling time requirement when the panel is touched.
Several solutions to this problem are available in the TSC2100. A programmable delay time is available which sets the
delay between turning the drivers on and making a conversion. This is referred to as the panel voltage stabilization time,
and is used in some of the modes available in the TSC2100. In other modes, the TSC2100 can be programmed to turn
on the drivers only without performing a conversion. Time can then be allowed before the command is issued to perform
a conversion.
The TSC2100 touch screen interface can measure position (X, Y) and pressure (Z). Determination of these coordinates
is possible under three different modes of the A/D converter: (1) conversion controlled by the TSC2100, initiated by
detection of a touch; (2) conversion controlled by the TSC2100, initiated by the host responding to the PINTDAV signal;
or (3) conversion completely controlled by the host processor.
Touch Screen A/D Converter
The analog inputs of the TSC2100 are shown in Figure 17. The analog inputs (X, Y, and Z touch panel coordinates, battery
voltage monitors, chip temperature and auxiliary input) are provided via a multiplexer to the successive approximation
register (SAR) analog-to-digital (A/D) converter. The A/D architecture is based on a capacitive redistribution architecture,
which inherently includes a sample/hold function.
A unique configuration of low on-resistance switches allows an unselected A/D input channel to provide power and an
accompanying pin to provide ground for driving the touch panel. By maintaining a differential input to the converter and a
differential reference input architecture, it is possible to negate errors caused by the driver switch on-resistances.
The A/D is controlled by an A/D converter control register. Several modes of operation are possible, depending upon the
bits set in the control register. Channel selection, scan operation, averaging, resolution, and conversion rate may all be
programmed through this register. These modes are outlined in the sections below for each type of analog input. The results
of conversions made are stored in the appropriate result register.
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PINTDAV
AVDD
VREF
DATAV
VREF
X+
X−
REFP
IN+
Y+
Y−
CONVERTER
IN−
REFM
VBAT2
VBAT1
AUX
AVSS
Figure 17. Simplified Diagram of the Analog Input Section
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Data Format
The TSC2100 output data is in unsigned binary format and can be read from the registers over the SPI interface.
Reference
The TSC2100 has an internal voltage reference that can be set to 1.25 V or 2.5 V,through the reference control register.
The internal reference voltage should only be used in the single-ended mode for battery monitoring, temperature
measurement, and for measuring the auxiliary inputs. Optimal touch screen performance is achieved when using a
ratiometric conversion, thus all touch screen measurements are done automatically in the ratiometric mode.
An external reference can also be applied to the VREF pin, and the internal reference can be turned off.
Variable Resolution
The TSC2100 provides three different resolutions for the A/D converter: 8-, 10- or 12-bits. Lower resolutions are often
practical for measurements such as touch pressure. Performing the conversions at lower resolution reduces the amount
of time it takes for the A/D converter to complete its conversion process, which lowers power consumption.
Conversion Clock and Conversion Time
The TSC2100 contains an internal 8-MHz clock, which is used to drive the state machines inside the device that perform
the many functions of the part. This clock is divided down to provide a clock to run the A/D converter. The division ratio for
this clock is set in the A/D converter control register. The ability to change the conversion clock rate allows the user to
choose the optimal value for resolution, speed, and power. If the 8-MHz clock is used directly, the A/D converter is limited
to 8-bit resolution; using higher resolutions at this speed may not result in accurate conversions. Using a 4-MHz conversion
clock is suitable for 10-bit resolution; 12-bit resolution requires that the conversion clock run at 1 or 2 MHz.
Regardless of the conversion clock speed, the internal clock runs nominally at 8 MHz. The conversion time of the TSC2100
is dependent upon several functions (see the section Touch Screen Conversion Initiated at Touch Detect in this data sheet).
While the conversion clock speed plays an important role in the time it takes for a conversion to complete, a certain number
of internal clock cycles is needed for proper sampling of the signal. Moreover, additional times, such as the panel voltage
stabilization time, can add significantly to the time it takes to perform a conversion. Conversion time can vary depending
upon the mode in which the TSC2100 is used. Throughout this data sheet, internal and conversion clock cycles are used
to describe the times that many functions take to execute. Considering the total system design, these times must be taken
into account by the user.
When both the audio ADC and DAC are powered down, the touch screen A/D uses an internal oscillator for conversions.
However, to save power whenever audio ADC or DAC are powered up, the internal oscillator is powered down and MCLK
and BCLK are used to clock the touch screen A/D.
The TSC2100 uses the programmed value of Page2, Reg 06H D13 and the PLL programmability to derive a clock from
MCLK. The various combinations are listed in Table 1.
Table 1. Conversion Clock Frequency
Page2, Reg 06H, D13 = 0
PLL enabled
PLL disabled
MCLK
P
K 13
160
MCLK 13
Q 10
Page2, Reg 06H, D13 = 1
MCLK
P
K 17
192
MCLK 17
Q 12
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Touch Detect/Data Available
The pen interrupt/data available (PINTDAV) output function is detailed in Figure 18. While in the power-down mode, the
Y– driver is ON and connected to AVSS and the X+ pin is connected through an on-chip pullup resistor to AVDD. In this
mode, the X+ pin is also connected to a digital buffer and mux to drive the PINTDAV output. When the panel is touched,
the X+ input is pulled to ground through the touch screen, and the pen−interrupt signal goes LOW due to the current path
through the panel to AVSS, initiating an interrupt to the processor. During the measurement cycles for X− and Y− position,
the X+ input is disconnected from the pen-interrupt circuit to prevent any leakage current from the pullup resistor flowing
through the touch screen, and thus causing conversion errors.
DATAV
PINTDAV
Temp1
Temp2
50 kΩ
Y+
High Except When
Temp1, Temp2 Activated
Temp
Diode
X+
Y−
ON
Y+ or X+ Drivers On or
Temp1, Temp2
Measurements Activated
Figure 18. PINTDAV Functional Block Diagram
In modes where the TSC2100 needs to detect if the screen is still touched (for example, when doing a PINTDAV initiated
X, Y, and Z conversion), the TSC2100 must reset the drivers so that the 50-kΩ resistor is connected. Because of the high
value of this pullup resistor, any capacitance on the touch screen inputs causes a long delay time, and may prevent the
detection from occurring correctly. To prevent this, the TSC2100 has a circuit that allows any screen capacitance to be
precharged, so that the pullup resistor does not have to be the only source for the charging current. The time allowed for
this precharge, as well as the time needed to sense if the screen is still touched, can be set in the configuration control
register D5−D0 of REG05H/Page1.
This does point out, however, the need to use the minimum capacitor values possible on the touch screen inputs. These
capacitors may be needed to reduce noise, but too large a value increases the needed precharge and sense times, as well
as panel voltage stabilization time.
The function of PINTDAV output is programmable and controlled by writing to the bits D15−D14 of REG 01H/Page1 as
described in the Table 2.
Table 2. Programmable PINTDAV Functionality
D15−D14
PINTDAV FUNCTION
00
Acts as PEN interrupt (active low) only. When PEN touch is detected, PINTDAV goes low.
01
Acts as data available (active low) only. The PINTDAV goes low as soon as one set of ADC conversions are completed for data
of X,Y, XYZ, battery input, or auxiliary input selected by D13−D10 in REG00H/Page1. The resulting A/D output is stored in the
appropriate registers. The PINTDAV remains low and goes high only after this complete set of registers selected by D13−D10
REG00H/Page1 is read out.
10
11
Acts as both PEN interrupt and data available. When PEN touch is detected, PINTDAV goes low and remains low. The PINTDAV
goes high only after one set of A/D conversions is completed for data of X,Y, XYZ, battery input, or auxiliary input selected by
D13−D10 in REG00H/Page1.
NOTE: See the section Conversion Time Calculation for the TSC2100 in this data sheet for the timing diagrams.
Pen-touch detect circuit is disabled during hardware power down.
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Touch Screen Measurements
The touch screen ADC can be controlled by the host processor or can be self−controlled to offload processing from the
host processor. Bit D15 of REG00H/Page1 sets the control mode of the TSC2100 touch screen ADC.
Conversion Controlled by TSC2100 Initiated at Touch Detect
In this mode, the TSC2100 detects when the touch panel is touched and causes the PINTDAV line to go low. At the same
time, the TSC2100 starts up its internal clock. Assuming the part was configured to convert XY coordinates, it then turns
on the Y drivers, and after a programmed panel voltage stabilization time, powers up the ADC and converts the Y
coordinate. If averaging is selected, several conversions may take place; when data averaging is complete, the Y
coordinate result is stored in the Y register.
If the screen is still touched at this time, the X drivers are enabled, and the process repeats, but measuring instead the X
coordinate, storing the result in the X register.
If only X and Y coordinates are to be measured, then the conversion process is complete. The time it takes to complete
this process depends upon the selected resolution, internal conversion clock rate, averaging selected, panel voltage
stabilization time, and precharge and sense times.
If the pressure of the touch is also to be measured, the process continues in the same way, measuring the Z1 and Z2 values,
and placing them in the Z1 and Z2 registers. As before, this process time depends upon the settings described above.
See the section Conversion Time Calculation for the TSC2100 in this data sheet for timing diagrams and conversion time
calculations.
Conversion Controlled by TSC2100 Initiated by the Host
In this mode, the TSC2100 detects when the touch panel is touched and causes the pen-interrupt signal line to go low. The
host recognizes the interrupt request, and then writes to the ADC control register (D13−D10 REG00H/Page1) to select one
of the touch screen scan functions. The host can either choose to initiate one of the scan functions, in which case the
TSC2100 controls the driver turnons, and wait times (e.g. upon receiving the interrupt the host can initiate the continuous
scan function X−Y−Z1−Z2 after which the TSC2100 controls the rest of conversion). The host can also choose to control
each aspect of conversion by controlling the driver turnons and start of conversions. For example, upon receiving the
interrupt request, the host turns on the X drivers. After waiting for the settling time, the host then addresses the TSC2100
again, this time requesting an X coordinate conversion, and so on.
The main difference between this mode and the previous mode is that the host, not the TSC2100, controls the touch screen
scan functions.
See the section Conversion Time Calculation for the TSC2100 in this data sheet for timing diagrams and conversion time
calculations.
Temperature Measurement
In some applications, such as battery recharging, a measurement of ambient temperature is required. The temperature
measurement technique used in the TSC2100 relies on the characteristics of a semiconductor junction operating at a fixed
current level. The forward diode voltage (VBE) has a well-defined characteristic versus temperature. The ambient
temperature can be predicted in applications by knowing the 25°C value of the VBE voltage and then monitoring the delta
of that voltage as the temperature changes.
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The TSC2100 offers two modes of temperature measurement. The first mode requires a single reading to predict the
ambient temperature. A diode, as shown in Figure 19, is used during this measurement cycle. This voltage is typically 600
mV at 25°C with a 20-µA current through it. The absolute value of this diode voltage can vary a few millivolts. During the
final test of the end product, the diode voltage must be stored at a known temperature. Further calibration can be done to
calculate the precise temperature coefficient of the particular device. This method has a temperature resolution of
approximately 0.3 °C/LSB and accuracy of approximately 1°C.
X+
MUX
A/D
Converter
Temperature Select
TEMP0 TEMP1
Figure 19. Functional Block Diagram of Temperature Measurement Mode
The second mode uses a two-measurement (differential) method. This mode requires a second conversion with a current
82 times larger. The voltage difference between the first (TEMP1) and second (TEMP2) conversion, using 82 times the
bias current, is represented by:
ǒkTqǓ
ln(N)
where:
N is the current ratio = 82
k = Boltzmann’s constant (1.38054 • 10−23 electrons volts/degrees Kelvin)
q = the electron charge (1.602189 • 10−19 °C)
T = the temperature in degrees Kelvin
This method provides resolution of approximately 1.5°C/LSB and accuracy of approximately 1°C. The equation for the
relation between differential code and temperature may vary slightly from device to device and can be calibrated at final
system test by the user.
2700
2500
ADC Code
2300
2100
1900
1700
1500
−40
−20
0
20
40
Temperature − °C
60
80
Figure 20. Typical Plot for Single Measurement Method
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500
Differential Code
450
400
350
300
−40
−20
0
20
40
60
80
Temperature − °C
Figure 21. Typical Plot for Differential Measurement Method
Temperature measurement can only be done in host controlled mode.
Battery Measurement
An added feature of the TSC2100 is the ability to monitor the battery voltage on the other side of a voltage regulator (dc/dc
converter), as shown in Figure 22. The battery voltage can vary from 0.5 V to 6 V while maintaining the analog supply
voltage to the TSC2100 in the range of 2.7 V to 3.6 V. The input voltage (VBAT1 or VBAT2) is divided down by a factor of
6 so that a 6.0-V battery voltage is represented as 1.0 V to the ADC. In order to minimize the power consumption, the divider
is only on during the sampling of the battery input. If the battery conversion results in a ADC output code of B, the voltage
at the battery pin can be calculated as
Vbat = (B/2^N)*6*Vref
where N is the programmed resolution of ADC and Vref the programmed value of internal reference or the applied external
reference.
DC/DC
Converter
+
Battery
−
VDD
VBAT
10 kΩ
2 kΩ
GND
Figure 22. Battery Measurement Functional Block Diagram
For increased protection and robustness, TI recommends a minimum 100 Ω resistor be added in series between the system
battery and the VBAT pin. The 100 Ω resistor will cause an approximately 1% gain change in the battery voltage
measurement, which can easily be corrected in software when the battery conversion data is read by the operating system.
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Battery measurement can only be done in host controlled mode.
See the section Conversion Time Calculation for the TSC2100 and subsection Non Touch Measurement Operation in this
data sheet for timing diagrams and conversion time calculations.
Auxiliary Measurement
The auxiliary voltage input (AUX) can be measured in much the same way as the battery inputs. Applications might include
external temperature sensing, ambient light monitoring for controlling the back-light, or sensing the current drawn from the
battery. The auxiliary input can also be monitored continuously in scan mode.
Auxiliary measurement can only be done in host controlled mode.
See the section Conversion Time Calculation for the TSC2100 and subsection Non Touch Measurement Operation in this
data sheet for timing diagrams and conversion time calculations.
Port Scan
If making measurements of BAT1, BAT2, and AUX is desired on a periodic basis, the port scan mode can be used. This
mode causes the TSC2100 to sample and convert both battery inputs and the auxiliary input. At the end of this cycle, the
battery and auxiliary result registers contain the updated values. Thus, with one write to the TSC2100, the host can cause
three different measurements to be made.
Port scan can only be done in host−controlled mode.
See the section Conversion Time Calculation for the TSC2100 and subsection Port Scan Operation in this data sheet for
timing diagrams and conversion time calculations.
Hardware Reset
The device requires hardware reset (active low) pulse after power up for correct operation. A hardware reset pulse initializes
all the internal registers, counters and logic.
Hardware Power Down
By default the PWD/ADWS pin is configured as a hardware power down (active low) signal. The device powers down all
the internal circuitry to save power. All the register contents are maintained. Some counters maintain their value. The user
can optionally use this pin as ADWS (ADC word select) by register programming. Putting the TSC2100 into hardware
power-down mode also disables the pen-touch detect circuit.
OPERATION−AUDIO CODEC
Audio Analog I/O
The TSC2100 has one mono audio input (MICIN) typically used for microphone recording, and an auxiliary input (AUX)
that can be used as a second microphone or line input. The dual audio output drivers have programmable power level and
can be configured to drive up to 325 mW into an 8-Ω speaker, or to drive 16-Ω stereo headphones at over 30-mW per
channel, or to provide a stereo line-level output. The power level of the output drivers is controlled using BIT−D12 in control
register REG−05H/Page2. The TSC2100 also has a virtual ground (VGND) output driver, which can optionally be used to
connect the return terminal of headphones, to eliminate the ac-coupling capacitors needed at the headphone output. The
VGND amplifier is controlled by BIT-D8 of REG−05H/Page2. A special circuit has also been included in the TSC2100 to
insert a short keyclick sound into the stereo audio output, even when the audio DAC is powered down. The keyclick sound
is used to provide feedback to the user when a particular button is pressed or item is selected. The specific sound of the
keyclick can be adjusted by varying several register bits that control its frequency, duration, and amplitude.
Audio Digital Interface
Digital audio data samples are transmitted between the TSC2100 and the CPU via the serial bus (BCLK, ADWS, DOUT,
LRCK, DIN) that can be configured to transfer digital data in four different formats: right justified, left justified, I2S, and DSP.
The four modes are MSB-first and operate with variable word length of 16, 20, 24, or 32 bits. The digital audio serial bus
of the TSC2100 can operate in master or slave mode, depending on its register settings. The word-select signals (ADWS,
LRCK) and bit clock signal (BCLK) are configured as outputs when the bus is in master mode. They are configured as inputs
when the bus is in slave mode. The ADWS is representative of the sampling rate of the audio ADC and is synchronized
with DOUT. The LRCK is representative of the audio DAC sampling rate and is synchronized with DIN. Although the DOUT
signal can contain two channels of information (a left and right channel), the TSC2100 sends the same ADC data in both
channels.
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D ADC/DAC SAMPLING RATE
The Audio Control 1 register (Register 00H, Page2) determines the sampling rates of the audio DAC and ADC, which
are scaled down from a reference rate (Fsref). The ADC and DAC can operate with either a common LRCK (equal
sampling rates) or separate ADWS and LRCK (unequal sampling rates). When the audio codec is powered up, it is by
default configured as an I2S slave with both the DAC and ADC operating at Fsref.
D WORD SELECT SIGNALS
The word select signal (LRCK, ADWS) indicates the channel being transmitted:
−
LRCK/ADWS = 0: left channel for I2S mode
−
LRCK/ADWS = 1: right channel for I2S mode
For other modes see the timing diagrams below.
Bitclock (BCLK) Signal
In addition to flexibility as master or slave mode, the BCLK can also be configured in two transfer modes—256−S and
Continuous Transfer Modes, which are described below. These modes are set using BIT−D12/REG−06h/Page2.
D 256−S TRANSFER MODE
In the 256−S mode, the BCLK rate always equals 256 times the maximum of the LRCK and ADWS frequencies. In the
256−S mode, the combination of 48 ksps sampling rate (as selected by BIT−D13/REG−06h/Page2) and left−justified
mode is not supported.
D CONTINUOUS TRANSFER MODE
In the continuous transfer mode, the BCLK rate always equals two times the word length of the maximum of the LRCK
and ADWS frequencies.
D RIGHT-JUSTIFIED MODE
In right-justified mode, the LSB of the left channel is valid on the rising edge of the BCLK preceding the falling edge of
ADWS or LRCK. Similarly the LSB of the right channel is valid on the rising edge of the BCLK preceding the rising edge
of ADWS or LRCK.
1/fs
ADWS/
LRCK
BCLK
Left Channel
DIN/
DOUT
0
n
MSB
n−1 n−2
Right Channel
2
1
0
n
n−1 n−2
2
1
0
LSB
Figure 23. Timing Diagram for Right-Justified Mode
D LEFT-JUSTIFIED MODE
In left−justified mode, the MSB of the right channel is valid on the rising edge of the BCLK, following the falling edge of
ADWS or LRCK. Similarly the MSB of the left channel is valid on the rising edge of the BCLK following the rising edge of
ADWS or LRCK.
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1/fs
ADWS/
LRCK
BCLK
Left Channel
DIN/
DOUT
n
n−1 n−2
2
Right Channel
1
0
MSB
n
n−1 n−2
2
1
0
n
n−1
LSB
Figure 24. Timing Diagram for Left-Justified Mode
D I2S MODE
In I2S mode, the MSB of the left channel is valid on the second rising edge of the BCLK after the falling edge of ADWS or
LRCK. Similarly the MSB of the right channel is valid on the second rising edge of the BCLK after the rising edge of
ADWS or LRCK.
1/fs
ADWS/
LRCK
BCLK
1 clock before MSB
Left Channel
DIN/
DOUT
n
n−1 n−2
2
1
MSB
Right Channel
0
n
n−1 n−2
2
1
0
n
LSB
Figure 25. Timing Diagram for I2S Mode
D DSP MODE
In DSP mode, the falling edge of ADWS or LRCK starts the data transfer with the left channel data first and immediately
followed by the right channel data. Each data bit is valid on the falling edge of BCLK.
1/fs
ADWS/
LRCK
BCLK
Left Channel
DIN/
DOUT
1
0
n
n−1 n−2
LSB MSB
2
Right Channel
1
0
n
n−1 n−2
2
LSB MSB
Figure 26. Timing Diagram for DSP Mode
26
1
0
n
n−1 n−2
LSB MSB
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AUDIO DATA CONVERTERS
The TSC2100 includes a stereo audio DAC and a mono audio ADC. Both ADC and DAC can operate with a maximum
sampling rate of 53 kHz and support all audio standard rates of 8 kHz, 11.025 kHz, 12kHz, 16kHz, 22.05 kHz, 24 kHz,
32kHz, 44.1 kHz, and 48 kHz. By utilizing the flexible clock generation capability and internal programmable interpolation,
a wide variety of sampling rates up to 53 kHz can be obtained from many possible MCLK inputs. In addition, the DAC and
ADC can independently operate at different sampling rates as indicated in control register REG−00H/Page2.
When the ADC or DAC is operating, the TSC2100 requires an applied audio MCLK input. The user should also set
BIT−D13/REG−06H/Page2 to indicate which Fsref rate is being used. If the codec ADC or DAC is powered up, then the
touch screen ADC uses MCLK and BCLK for its internal clocking, and the internal oscillator is powered down to save power.
Typical audio DACs can suffer from poor out-of-band noise performance when operated at low sampling rates, such as
8 kHz or 11.025 kHz. The TSC2100 includes programmable interpolation circuitry to provide improved audio performance
at such low sampling rates, by first upsampling low-rate data to a higher rate, filtering to reduce audible images, and then
passing the data to the internal DAC, which is actually operating at the Fsref rate. This programmable interpolation is
determined using BIT−D5−D3/REG−00H/Page2.
For example, if playback of 11.025-kHz data is required, the TSC2100 can be configured such that Fsref = 44.1 kHz. Then
using BIT−D5−D3/REG−00H/Page2, the DAC sampling rate (Fs) can be set to Fsref/4, or Fs = 11.025 kHz. In operation,
the 11.025-kHz digital input data is received by the TSC2100, upsampled to 44.1 kHz, and filtered for images. It is then
provided to the audio DAC operating at 44.1 kHz for playback. In reality, the audio DAC further upsamples the 44.1 kHz
data by a ratio of 128 x and performs extensive interpolation filtering and processing on this data before conversion to a
stereo analog output signal.
PLL
The TSC2100 has an on-chip PLL to generate the needed internal ADC and DAC operational clocks from a wide variety
of clocks available in the system. The PLL supports an MCLK varying from 2 MHz to 50 MHz and is register programmable
to enable generation of required sampling rates with fine precision.
ADC and DAC sampling rates are given by
DAC_FS = Fsref/N1 and ADC_FS = Fsref/N2
where, Fsref must fall between 39 kHz and 53 kHz, and N1, N2 =1, 1.5, 2, 3, 4, 5, 5.5, 6 are register programmable.
The PLL can be enabled or disabled using register programming.
D
When PLL is disabled
Fsref + MCLK
128 Q
Q = 2, 3…17
D
−
Note: For ADC, with N2 = 1.5 or 5.5, odd values of Q are not allowed.
−
In this mode, the MCLK can operate up to 50 MHz, and Fsref should fall within 32 kHz to 53 kHz.
When PLL is enabled
Fsref + MCLK
2048
K
P
P = 1, 2, 3, …, 8
K = J.D
J = 1, 2, 3, ….,64
D = 0, 1, 2, …, 9999
P, J, and D are register programmable, where J is integer part of K before the decimal point, and D is four-digit fractional
part of K after the decimal point, including lagging zeros.
Examples:
If K = 8.5, Then J = 8, D = 5000
If K = 7.12, Then J = 7, D = 1200
If K = 7.012, Then J = 7, D = 120
The PLL is programmed through Registers 1BH and 1CH of Page2.
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D
When PLL is enabled and D = 0, the following condition must be satisfied
2 MHz v MCLK v 20 MHz
P
80 MHz v MCLK
P
K v 110 MHz
4 v J v 55
D
When PLL is enabled and D ≠ 0, the following condition must be satisfied
10 MHz v MCLK v 20 MHz
P
80 MHz v MCLK
P
K v 110 MHz
4 v J v 11
Example 1:
For MCLK = 12 MHz and Fsref = 44.1 kHz
P = 1, K = 7.5264 ⇒ J = 7, D = 5264
Example 2:
For MCLK = 12 MHz and Fsref = 48.0 kHz
P = 1, K = 8.192 ⇒ J = 8, D = 1920
MONO AUDIO ADC
Analog Front End
The analog front end of the audio ADC consists of an analog MUX and a programmable gain amplifier (PGA). The MUX
can connect either the MICIN or AUX signal through the PGA to the ADC for audio recording. The TSC2100 also has an
option of choosing both MICIN and AUX as a differential input pair. The TSC2100 also includes a microphone bias circuit,
which can source up to 4 mA of current and is programmable to a 2 V or 2.5 V level. The bias block is powered down when
both the ADC and analog mixer blocks are powered down.
Because of the oversampling nature of the audio ADC and the integrated digital dicimation filtering, requirements for analog
antialiasing filtering are very relaxed. The TSC2100 integrates a second order analog antialiasing filter with 20-dB
attenuation at 1 MHz. This filter, combined with the digital decimal filter, provides sufficient antialiasing filtering without
requiring any external components.
The PGA allows analog gain control from 0 dB to 59.5 dB in steps of 0.5 dB. The PGA gain changes are implemented with
an internal soft-stepping algorithm that only changes the actual volume level by one 0.5-dB step every one or two ADC
output samples, depending on the register programming. This soft-stepping ensures that volume control changes occur
smoothly with no audible artifacts. Upon reset, the PGA gain defaults to a mute condition, and upon power down, the PGA
soft-steps the volume to mute before shutting down. A read-only flag (D0 control register 04H/Page2) is set whenever the
gain applied by PGA equals the desired value set by the register. The soft−stepping control can be disabled by
programming D15=1 in register 1DH of Page02. When soft stepping is enabled, the MCLK signal must be applied to the
part after the ADC power down register is written to ensure the soft-stepping to mute has completed. When the ADC power
down flag is no longer set, the MCLK signal can be shut down.
Delta-Sigma ADC
The analog-to-digital converter is a delta-sigma modulator with 128 times oversampling ratio. The ADC can support a
maximum output rate of 53 kHz.
Decimation Filter
The audio ADC includes an integrated digital decimation filter that removes high-frequency content and downsamples the
audio data from an initial sampling rate of 128 times Fs to the final output sampling rate of Fs. The decimation filter provides
a linear phase output response with a group delay of 17/Fs. The −3-dB bandwidth of the decimation filter extends to 0.45
Fs and scales with the sample rate (Fs)
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Automatic Gain Control (AGC)
Automatic gain control (AGC) can be used to maintain nominally constant output signal amplitude when recording speech
signals. This circuity automatically adjusts the PGA gain as the input signal becomes overly loud or very weak, such as
when a person speaking into a microphone moves closer or farther from the microphone. The AGC algorithm has several
programmable settings, including target gain, attack and decay time constants, noise threshold, and maximum PGA gain
applicable that allow the algorithm to be fine tuned for any particular application. The algorithm uses the absolute average
of the signal (which is the average of the absolute value of the signal) as a measure of the nominal amplitude of the output
signal.
Target gain represents the nominal output level at which the AGC attempts to hold the ADC output signal level. The
TSC2100 allows programming of eight different target gains, which can be programmed from −5.5 dB to −24 dB relative
to a full-scale signal. Since the TSC2100 reacts to the signal absolute average and not to peak levels, it is recommended
that the larger gain be set with enough margin to avoid clipping at the occurrence of loud sounds.
Attack time determines how quickly the AGC circuitry reduces the PGA gain when the input signal is too loud. It can be
varied from 8 ms to 20 ms.
Decay time determines how quickly the PGA gain is increased when the input signal is too low. It can be varied in the range
from 100 ms to 500 ms.
Noise threshold determines level below which if the input speech average value falls, AGC considers it as a silence and
hence brings down the gain to 0 dB in steps of 0.5 dB every FS and sets noise threshold flag. The gain stays at 0 dB unless
the input speech signal average rises above noise threshold setting. This ensures that noise does not get gained up in the
absence of speech. Noise threshold level in the AGC algorithm is programmable from −60 dB to −90 dB relative to full scale.
This operation includes debounce and hysteresis to avoid the AGC gain from cycling between high gain and 0 dB when
signals are near the noise threshold level. When noise threshold flag is set, status of gain applied by AGC and saturation
flag should be ignored.
Maximum PGA applicable allows user to restrict maximum gain applied by AGC. This can be used for limiting PGA gain
in situations where environmental noise is greater than programmed noise threshold. It can be programmed from 0 dB to
59.5 dB in steps of 0.5 dB.
See Table 3 for various AGC programming options.
Input
Signal
Output
Signal
Target Gain
AGC
Gain
Decay Time
Attack Time
Figure 27. AGC Characteristics
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Table 3. AGC Settings
MIC INPUT
BIT
CONTROL REGISTER
AGC enable
D0
01H
Target gain
D7−D5
01H
Time constants (attack and decay time)
D4−D1
01H
Noise threshold
D5−D4
06H
Noise threshold flag
D11
04H
Hysteresis
D10−D9
1DH
Debounce time (normal to silence mode)
D8−D6
1EH
Debounce time (silence to normal mode)
D5−D3
1EH
Max PGA applicable
D15−D9
1EH
Gain applied by AGC
D15−D8
01H
D0
04H
D3
06H
Saturation flag
Clip stepping enable
NOTE: All settings shown in Table 2 are located in page2 of control registers.
STEREO AUDIO DAC
Each channel of the stereo audio DAC consists of a digital audio processing block, a digital interpolation filter, digital
delta-sigma modulator, and an analog reconstruction filter. The DAC is designed to provide enhanced performance at low
sample rates through increased oversampling and image filtering, thereby keeping quantization noise generated within the
delta-sigma modulator and signal images strongly suppressed within the audio band to beyond 20 kHz. This is realized
by keeping the upsampled rate constant at 128 x Fsref and changing the oversampling ratio as the input sample rate is
changed. For Fsref of 48 kHz, the digital delta-sigma modulator always operates at a rate of 6.144 MHz. This ensures that
quantization noise generated within the delta-sigma modulator stays low within the frequency band below 20 kHz at all
sample rates. Similarly, for Fsref rate of 44.1 kHz, the digital delta-sigma modulator always operates at a rate of 5.6448
MHz.
Digital Audio Processing
The DAC channel consists of optional filters for de-emphasis and bass, treble, midrange level adjustment, or speaker
equalization. The de-emphasis function is only available for sample rates of 32 kHz, 44.1 kHz, and 48 kHz. The transfer
function consists of a pole with time constant of 50 µs and a zero with time constant of 15 µs. Frequency response plots
are given in the Audio Codec Filter Frequency Responses section of this data sheet.
The DAC digital effects processing block also includes a fourth order digital IIR filter with programmable coefficients (one
set per channel). The filter is implemented as cascade of two biquad sections with frequency response given by:
ǒ
Ǔǒ
N0 ) 2 N1 z *1 ) N2 z *2
32768 * 2 D1 z *1 * D2 z *2
Ǔ
N3 ) 2 N4 z *1 ) N5 z *2
32768 * 2 D4 z *1 * D5 z *2
The N and D coefficients are fully programmable, and the entire filter can be enabled or bypassed. The coefficients for this
filter implement a variety of sound effects, with bass-boost or treble boost being the most commonly used in portable audio
applications. The default N and D coefficients in the part are given by:
N0 = N3 = 27619
N1 = N4 = −27034
D1 = D4 = 32131
D2 = D5 = −31506
N2 = N5 = 26461
and implement a shelving filter with 0 dB gain from dc to approximately 150 Hz, at which point it rolls off to a 3 dB attenuation
for higher frequency signals, thus giving a 3-dB boost to signals below 150 Hz. The N and D coefficients are represented
by 16-bit twos complement numbers with values ranging from –32768 to +32767. Frequency response plots are given in
the Audio Codec Filter Frequency Responses section of this data sheet.
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Interpolation Filter
The interpolation filter upsamples the output of the digital audio processing block by the required oversampling ratio. It
provides a linear phase output with a group delay of 21/Fs.
In addition, programmable digital interpolation filtering is included to provide enhanced image filtering and reduce signal
images caused by the upsampling process that are below 20 kHz. For example, upsampling an 8-kHz signal produces
signal images at multiples of 8 kHz (i.e., 8 kHz, 16 kHz, 24 kHz, etc). The images at 8 kHz and 16 kHz are below 20 kHz
and still audible to the listener; therefore, they must be filtered heavily to maintain a good quality output. The interpolation
filter is designed to maintain at least 65-dB rejection of images that land below 7.455 Fs. In order to utilize the programmable
interpolation capability, the Fsref should be programmed to a higher rate (restricted to be in the range of 39 kHz to 53 kHz
when the PLL is in use), and the actual Fs is set using the dividers in BIT−D5−D3/REG−00H/Page2. For example, if Fs
= 8 kHz is required, then Fsref can be set to 48 kHz, and the DAC Fs set to Fsref/6. This ensures that all images of the
8-kHz data are sufficiently attenuated well beyond a 20-kHz audible frequency range.
Delta-Sigma DAC
The audio digital-to-analog converter incorporates a third order multibit delta-sigma modulator followed by an analog
reconstruction filter. The DAC provides high-resolution, low-noise performance, using oversampling and noise shaping
techniques. The analog reconstruction filter design consists of a 6 tap analog FIR filter followed by a continuous time RC
filter. The analog FIR operates at a rate of 128 x Fsref (6.144 MHz when Fsref = 48 kHz, 5.6448 MHz when Fsref = 44.1 kHz).
Note that the DAC analog performance may be degraded by excessive clock jitter on the MCLK input. Therefore, care must
be taken to keep jitter on this clock to a minimum.
DAC Digital Volume Control
The DAC has a digital volume control block, which implements programmable gain. The volume level can be varied from
0dB to –63.5 dB in 0.5 dB steps, in addition to a mute bit, independently for each channel. The volume level of both channels
can also be changed simultaneously by the master volume control. The gain is implemented with a soft-stepping algorithm,
which only changes the actual volume by one step per input sample, either up or down, until the desired volume is reached.
The rate of soft-stepping can be slowed to one step per two input samples through bit D1 of control register 04H/Page2.
Because of soft-stepping, the host does not know when the DAC has been actually muted. This may be important if the
host wishes to mute the DAC before making a significant change, such as changing sample rates. In order to help with this
situation, the TSC2100 provides a flag back to the host via a read-only register bit (D2−D3 of control register 04H/Page2)
that alerts the host when the part has completed the soft-stepping and the actual volume has reached the desired volume
level. The soft-stepping feature can be disabled by programming D14=1 in register 1DH in Page02. If soft-stepping is
enabled, the MCLK signal should be kept applied to the device until the DAC power-down flag is set. When this flag is set,
the internal soft-stepping process and power down sequence is complete, and the MCLK can be stopped if desired.
The TSC2100 also includes functionality to detect when the user switches on or off the de-emphasis or digital audio
processing functions, to first (1) soft-mute the DAC volume control, (2) change the operation of the digital effects
processing, and (3) soft-unmute the part. This avoids any possible pop/clicks in the audio output due to instantaneous
changes in the filtering. A similar algorithm is used when first powering up or down the DAC. The circuit begins operation
at power up with the volume control muted, then soft-steps it up to the desired volume level. At power down, the logic first
soft-steps the volume down to a mute level, then powers down the circuitry.
DAC Powerdown
The DAC powerdown flag ( D6 of REG05H/Page2) along with D10 of REG05H/Page2 denotes the powerdown status of
the DAC according to Table 4.
Table 4. DAC Powerdown Status
[D10,D6]
POWERUP / DOWN STATE OF DAC
[0,0]
DAC is in stable powerup state
[0,1]
DAC is in the process of powering up. The length of this state is determined by PLL and output driver
powerup delays controlled by register programming.
[1,0]
DAC is in the process of powering down. The length of this state is determined by soft-stepping of volume
control block and DAC pop reduction sequencing controlled by register programming.
[1,1]
DAC is in a stable powerdown state.
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AUDIO OUTPUT DRIVERS
The TSC2100 features audio output drivers which can be configured in either low power mode or high power mode
depending on the load and output power required. By default, at reset the output drivers are configured in low power mode.
In this mode, the output drivers can drive a full-scale line-level signal into loads of 10 kΩ minimum or drive moderate
amplitude signals into loads of 16 Ω minimum.
The output drivers can also be configured in high power mode by setting bit D12 of Reg05H/Page2 to 1. In this mode, each
output driver can deliver up to 30 mW per channel into a headphone speaker load of 16 Ω. The headphones can be
connected in a single ended configuration using ac-coupling capacitors, or the capacitors can be removed and virtual
ground (VGND) powered for a capless output connection. The typical headphone jack configuration for these two modes
is shown in Figure 30. Note that the VGND amplifier must be powered if the capless configuration is used.
In the case of an ac-coupled output, the value of the capacitors is typically chosen based on the amount of low-frequency
cut that can be tolerated. The capacitor in series with the load impedance forms a high-pass filter with −3 dB cutoff frequency
of 1/(2πRC) in Hz, where R is the impedance of the headphones. Use of an overly small capacitor reduces low-frequency
components in the signal output and lead to low-quality audio. When driving 16-Ω headphones, capacitors of 220-µF (a
commonly used value) result in a high-pass filter cutoff frequency of 45 Hz, although reducing these capacitors to 50 µF
results in a cutoff frequency of 199 Hz, which is generally considered noticeable when playing music. The cutoff frequency
is reduced to half of the above values if 32-Ω headphones are used instead of 16 Ω.
The TSC2100 programmable digital effects block can be used to help reduce the size of capacitors needed by implementing
a low frequency boost function to help compensate for the high-pass filter introduced by the ac-coupling capacitors. For
example, by using 50-µF capacitors and setting the TSC2100 programmable filter coefficients as shown below, the
frequency response can be improved as shown in Figure 29.
Filter coefficients (use the same for both channels):
N0 = 32767, N1 = −32346, N2 = 31925, N3 = 32767, N4 = 0, N5 = 0
D0 = 32738, D1 = −32708 D4 = 0, D5 = 0
0
−2
−4
Gain − dB
−6
−8
−10
−12
−14
−16
−18
−20
0
100 200 300 400 500 600 700 800 900 1 k
f − Frequency − Hz
Figure 28. Uncompensated Response For 16- Load and 50-F Decoupling Capacitor
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0
Gain − dB
−5
−10
−15
−20
0
100 200 300 400 500 600 700 800 900 1 k
f − Frequency − Hz
Figure 29. Frequency Response For 16- Load and 50-F Decoupling Capacitor After Gain
Compensation Using Above Set of Coefficients for Audio Effects Filter
Using the capless output configuration eliminates the need for these capacitors and removes the accompanying high-pass
filter entirely. However, this configuration does have one drawback – if the RETURN terminal of the headphone jack (which
is wired to the TSC2100 VGND pin) is ever connected to a ground, that is shorted to the TSC2100 ground pin, then the
VGND amplifier enters short-circuit protection, and the audio output does not function properly.
TSC2100
TSC2100
HPR
HPR
HPL
HPL
VGND
Headphone Jack
VGND
Headphone Jack
Figure 30. Headphone Configurations, AC-Coupled (left) and Capless (right)
The audio output drivers in high power mode can also be configured to drive a mono differential signal into a speaker load
of 8-Ω minimum. The speaker load should be connected differentially between the HPR and HPL outputs. There are several
options for playback of DAC data in this case. If a stereo digital signal is available, this signal can be sent in normal stereo
fashion to the audio DAC. The programmable digital effects filters can then be used to invert one channel, so that the signal
applied across the speaker load is (LEFT + RIGHT), or effectively a mono-mix of the two channels. A simple example of
how to implement this inversion using the programmable filters is to set the coefficients as follows:
Left−channel coefficients:
N0=32767, N1=0, N2=0, N3=32767, N4=0, N5=0
D1=0, D2=0, D4=0, D5=0
Right−channel coefficients: N0=−32767, N1=0, N2=0, N3=32767, N4=0, N5=0
D1=0, D2=0, D4=0, D5=0
This provides no spectral shaping, it only inverts the right channel relative to the left channel, such that the signals at HPL
and HPR are (LEFT) and (−RIGHT), with the signal across the speaker then being LEFT+ RIGHT. In a general case when
spectral shaping is also desired, the inversion can be accomplished simply by setting N0, N1, and N2 coefficients of one
channel to the negative of the values set for the other channel. Note that the programmable filtering must be enabled by
setting BIT−D1/REG−05H/Page2 to 1.
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To enable the output drivers to deliver higher output power, the DAC output swing should be set to its highest level by setting
BIT−D10−D9/REG−06H/Page2 to 11. It is possible to increase power even further by disabling the built-in short-circuit
protection by programming bit D8 of Reg1DH/Page2 to 1. In this case care must be taken so a short-circuit at the output
does not occur. Figure 31 shows a typical jack configuration using a capless output configuration. In this configuration, the
TSC2100 drives the loudspeaker whenever headphones are not inserted in the jack and drives the headphones whenever
it is inserted in the jack.
TSC2100
HPR
HPL
Headphone Jack
VGND
Loud Speaker
Figure 31. Speaker Connection
0
THD − Total Harmonic Distortion − dB
−10
−20
2.402 VPP
−30
−40
−50
2 VPP
−60
−70
−80
−90
−100
0
50
100
150
200
250
300
350
PO − Output Power − mW
Figure 32. THD vs Output Power Delivered to an an 8- Load (255C, AVDD = DRVDD = 3.3 V, DVDD = 1.8
V, DAC Output Swing Set to 2 V and 2.4V, and Short-Circuit Protection Disabled)
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0
THD − Total Harmonic Distortion − dB
−10
−20
−30
−40
−50
−60
−70
−80
−90
−100
2.7
2.8
2.9
3
3.1
3.2
3.3
3.4
3.5
3.6
AVDD, DRVDD − V
Figure 33. THD vs AVDD, DRVDD Supply Voltage (255C When Driving a −1 dB, 1-kHz Sinewave From the
DAC Into an 8- Load, with DAC Output Swing Set to 2.4 V, and Short-Circuit Protection Disabled)
The TSC2100 incorporates a programmable short-circuit detection/protection function with different modes of operation.
During the insertion or removal of a headphone plug from the jack, the output pins of the drivers may be accidentally shorted,
causing the part to potentially draw a huge current, which may cause the power supply voltages to dip. Bits D8−D7 of
REG−1DH/Page2 control how the short-circuit detection/protection operates in the TSC2100. One option is to fully disable
short-circuit protection, which also enables the audio output drivers to deliver more power to a low-impedance load (such
as an 8-Ω speaker). However, care must be taken to prevent any short-circuit from occurring while the part is in this mode.
A second programmable configuration enables current-limiting in the audio output drivers, so that excessive currents
cannot be provided if the outputs are shorted. It also enables the internal short-circuit detection function, which can detect
excess current being drawn from the drivers and set a short circuit detect flag (Page2, REG−1DH, BIT−D6). This flag can
be read by the user to powerdown the drivers if desired. This flag is cleared only if the short-circuit condition is removed.
If the user does not monitor this flag and powers down the drivers when a short-circuit occurs, the current-limiting prevents
excessive currents from being drawn, but power dissipation is higher due to this limited current flowing through the short.
In a third programmable configuration, the TSC2100 can be programmed to monitor and automatically powerdown the
audio output drivers upon detection of a short-circuit condition (Page2, REG−1DH, BIT−D7), in addition to setting the
short-circuit flag in Page2, REG−1DH, BIT−D6. When the device has detected a short and resulted in this condition, the
short-circuit flag is cleared when all the routings to the speaker driver are disabled (i.e. DAC, Analog Mixer, and Keyclick
blocks are powered down by user).
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AUDIO OUTPUT DRIVER POWER-ON POP REDUCTION SCHEME
The TSC2100 implements a pop reduction scheme to reduce audible artifacts during powerup and powerdown of the audio
output drivers. This scheme can be controlled by programming bits D2 and D1 of REG1EH/Page2. By default, the driver
pop reduction scheme is enabled and can be disabled by programming bit D2 of Reg1EH/Page2 to 1. When this scheme
is enabled and the virtual ground connection is not used (VGND amplifier is powered down), the audio output driver slowly
charges up any external ac-coupling capacitors to reduce audible artifacts. Bit D1 of REG1EH/Page2 provides control of
the charging time for the ac-coupling capacitor as either 0.8 sec or 4 sec. When the virtual ground amplifier is powered up
and used, the external ac-coupling capacitor is eliminated, and the powerup time becomes either 1 ms or 5 ms. This scheme
takes effect whenever the audio output drivers are powered up due to enabling any of the DAC, the Analog Mixer or the
Keyclick Generator.
Pop Reduction For DAC Routing
Whenever the audio DAC is powered on or off, there may be a slight change in the output dc offset voltage and can be heard
as a weak pop in the output. In order to reduce this artifact, the TSC2100 implements a DAC pop reduction scheme, which
is programmable using bits D5−D2 in REG−1DH/Page2. Bit D5 enables the scheme, which implements a slow transition
between the starting dc level and the final dc level. For best results program D4−D2 in REG1DH/Page2 to 100.
AUDIO MIXING
Digital Sidetone
The digital sidetone control attenuates the output from the ADCs decimation filter and routes its output to be mixed with
the DAC digital input. If bit D7 of REG−03H/Page2 is reset, the output of the sidetone control is mixed with the stereo DAC
input. Care must be taken while selecting the digital sidetone gain such that the output of the digital mixer is not overloaded.
The digital sidetone block implements gains from 0 dB to –48 dB in steps of 1.5 dB. Gain changes are implemented at
zero-crossings of the signal to avoid any audible artifacts. The digital sidetone block is automatically internally disabled
if ADC and DAC are operating at different sampling rates, or if the DAC is powered down.
Analog Mixer
The analog mixer can be used to route the analog input selected for the ADC (MICIN or AUX) through an analog volume
control and then mix it with the audio DAC output. The analog mixer feature is available only if single-ended MICIN or AUX
is selected as the input to the ADC, not when the ADC input is configured in fully-differential mode. This feature is available
even if the ADC and DAC are powered down. The analog volume control in this path has a gain range from 12 dB to
–34.5 dB in 0.5-dB steps plus mute and includes soft-stepping logic. The internal oscillator is used for soft stepping
whenever the ADC and DAC are powered down.
KEYCLICK
A special circuit has been included for inserting a square−wave signal into the analog output signal path based on register
control. This functionality is intended for generating keyclick sounds for user feedback. Register 04H/Page2 contains bits
that control the amplitude, frequency, and duration of the square-wave signal. The frequency of the signal can be varied
from 62.5 Hz to 8 kHz and its duration can be programmed from 2 periods to 32 periods. Whenever this register is written,
the square-wave is generated and coupled into the audio output, going to both audio outputs. The keyclick enable bit D15
of control register 04H/Page2 is reset after the duration of keyclick is played out. This capability is available even when
the ADC and DAC are powered down.
SPI DIGITAL INTERFACE
All TSC2100 control registers are programmed through a standard SPI bus. The SPI allows full-duplex, synchronous, serial
communication between a host processor (the master) and peripheral devices (slaves). The SPI master generates the
synchronizing clock and initiates transmissions. The SPI slave devices depend on a master to start and synchronize
transmissions.
A transmission begins when initiated by a master SPI. The byte from the master SPI begins shifting in on the slave SPIDIN
(MOSI) pin under the control of the master serial clock. As the byte shifts in on the SPIDIN pin, a byte shifts out on the
SPIDOUT (MISO) pin to the master shift register.
The idle state of the serial clock for the TSC2100 is low, which corresponds to a clock polarity setting of 0 (typical
microprocessor SPI control bit CPOL = 0). The TSC2100 interface is designed so that with a clock phase bit setting of 1
(typical microprocessor SPI control bit CPHA = 1), the master begins driving its MOSI pin and the slave begins driving its
SPIDOUT pin on the first serial clock edge. The SS pin can remain low between transmissions; however, the TSC2100
only interprets command words which are transmitted after the falling edge of SS.
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TSC2100 COMMUNICATION PROTOCOL
Register Programming
The TSC2100 is entirely controlled by registers. Reading and writing these registers is controlled by an SPI master and
accomplished by the use of a 16-bit command, which is sent prior to the data for that register. The command is constructed
as shown in Figure 34.
The command word begins with a R/W bit, which specifies the direction of data flow on the SPI serial bus. The following
4 bits specify the page of memory this command is directed to, as shown in Table 5. The next six bits specify the register
address on that page of memory to which the data is directed. The last five bits are reserved for future use and should be
written only with zeros.
Table 5. Page Addressing
PG3
PG2
PG1
PG0
0
0
0
0
PAGE ADDRESSED
0
0
0
0
1
1
0
0
1
0
2
0
0
1
1
Reserved
0
1
0
0
Reserved
0
1
0
1
Reserved
0
1
1
0
Reserved
0
1
1
1
Reserved
1
0
0
0
Reserved
1
0
0
1
Reserved
1
0
1
0
Reserved
1
0
1
1
Reserved
1
1
0
0
Reserved
1
1
0
1
Reserved
1
1
1
0
Reserved
1
1
1
1
Reserved
To read all the first page of memory, for example, the host processor must send the TSC2100 the command 0x8000 – this
specifies a read operation beginning at page 0, address 0. The processor can then start clocking data out of the TSC2100.
The TSC2100 automatically increments its address pointer to the end of the page; if the host processor continues clocking
data out past the end of a page, the TSC2100 sends back the value 0xFFFF.
Likewise, writing to page 1 of memory consists of the processor writing the command 0x0800, which specifies a write
operation, with PG0 set to 1, and all the ADDR bits set to 0. This results in the address pointer pointing at the first location
in memory on Page 1. See the section on the TSC2100 memory map for details of register locations
BIT 15
MSB
BIT 14
BIT 13
BIT 12
BIT 11
BIT 10
BIT 9
BIT 8
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
LSB
R/W*
PG3
PG2
PG1
PG0
ADDR5
ADDR4
ADDR3
ADDR2
ADDR1
ADDR0
0
0
0
0
0
Figure 34. TSC2100 Command Word
37
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SS
SCLK
MOSI
COMMAND WORD
DATA
DATA
Figure 35. Write Operation for TSC2100 SPI Interface
SS
SCLK
MOSI
MISO
COMMAND WORD
DATA
Figure 36. Read Operation for TSC2100 SPI Interface
38
DATA
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SLAS378− NOVEMBER 2003
TSC2100 MEMORY MAP
The TSC2100 has several 16-bit registers which allow control of the device as well as providing a location for results from
the TSC2100 to be stored until read by the host microprocessor. These registers are separated into three pages of memory
in the TSC2100: a data page (Page 0) and control pages (Page 1 and Page 2). The memory map is shown in Table 6.
Table 6. Memory Map
Page 0: Touch Screen Data Registers
ADDR
Page 1: Touch Screen Control Registers
REGISTER
ADDR
REGISTER
Page 2: Audio Control Registers
ADDR
REGISTER
00
X
00
TSC ADC
00
Audio Control 1
01
Y
01
Status
01
Codec ADC Gain
02
Z1
02
Reserved
02
Codec DAC Gain
03
Z2
03
Reference
03
Codec Sidetone
04
Reserved
04
Reset
04
Audio Control 2
05
BAT1
05
Configuration
05
Codec Power Control
06
BAT2
06
Reserved
06
Audio Control 3
07
AUX
07
Reserved
07
Digital Audio Effects Filter Coefficients
08
Reserved
08
Reserved
08
Digital Audio Effects Filter Coefficients
09
TEMP1
09
Reserved
09
Digital Audio Effects Filter Coefficients
0A
TEMP2
0A
Reserved
0A
Digital Audio Effects Filter Coefficients
0B
Reserved
0B
Reserved
0B
Digital Audio Effects Filter Coefficients
0C
Reserved
0C
Reserved
0C
Digital Audio Effects Filter Coefficients
0D
Reserved
0D
Reserved
0D
Digital Audio Effects Filter Coefficients
0E
Reserved
0E
Reserved
0E
Digital Audio Effects Filter Coefficients
0F
Reserved
0F
Reserved
0F
Digital Audio Effects Filter Coefficients
10
Reserved
10
Reserved
10
Digital Audio Effects Filter Coefficients
11
Reserved
11
Reserved
11
Digital Audio Effects Filter Coefficients
12
Reserved
12
Reserved
12
Digital Audio Effects Filter Coefficients
13
Reserved
13
Reserved
13
Digital Audio Effects Filter Coefficients
14
Reserved
14
Reserved
14
Digital Audio Effects Filter Coefficients
15
Reserved
15
Reserved
15
Digital Audio Effects Filter Coefficients
16
Reserved
16
Reserved
16
Digital Audio Effects Filter Coefficients
17
Reserved
17
Reserved
17
Digital Audio Effects Filter Coefficients
18
Reserved
18
Reserved
18
Digital Audio Effects Filter Coefficients
19
Reserved
19
Reserved
19
Digital Audio Effects Filter Coefficients
1A
Reserved
1A
Reserved
1A
Digital Audio Effects Filter Coefficients
1B
Reserved
1B
Reserved
1B
PLL Programmability
1C
Reserved
1C
Reserved
1C
PLL Programmability
1D
Reserved
1D
Reserved
1D
Audio Control 4
1E
Reserved
1E
Reserved
1E
Audio Control 5
1F
Reserved
1F
Reserved
1F
Reserved
39
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TSC2100 CONTROL REGISTERS
This section describes each of the registers shown in the memory map of Table 6. The registers are grouped according
to the function they control. In the TSC2100, bits in control registers can refer to slightly different functions depending upon
whether you are reading the register or writing to it.
TSC2100 Data Registers (Page 0)
The data registers of the TSC2100 hold data results from conversion of touch screen ADC. All of these registers default
to 0000H upon reset. These registers are read only.
X, Y, Z1, Z2, BAT1, BAT2, AUX, TEMP1 and TEMP2 Registers
The results of all A/D conversions are placed in the appropriate data register. The data format of the result word, R, of these
registers is right-justified, as follows:
BIT 15
MSB
BIT 14
BIT 13
BIT 12
BIT 11
BIT 10
BIT 9
BIT 8
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
LSB
0
0
0
0
R11
MSB
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
R0
LSB
PAGE 1 CONTROL REGISTER MAP
REGISTER 00H: Touch Screen ADC Control
BIT
NAME
RESET VALUE
D15
PSTCM
0(for read status)
0(for write status)
Pen Status/Control Mode.
READ
0 => There is no screen touch (default)
1 => The pen is down
WRITE
0 => Host controlled touch screen conversions(default).
1=> TSC2100 controlled touch screen conversions.
D14
ADST
1(for read status)
0(for write status)
A/D Status.
READ
0 => ADC is busy
1 => ADC is not busy (default)
WRITE
0 => Normal mode. (default)
1 => Stop conversion and power down. Power down happens immediately
D13−10
ADSCM
0000
40
FUNCTION
A/D Scan Mode.
0000 => No scan
0001 => Touch screen scan function: X and Y coordinates are converted and the results returned
to X and Y data registers. Scan continues until either the pen is lifted or a stop bit is sent.
0010 => Touch screen scan function: X, Y, Z1 and Z2 coordinates are converted and the results
returned to X, Y, Z1 and Z2 data registers. Scan continues until either the pen is lifted or
a stop bit is sent.
0011 => Touch screen scan function: X coordinate is converted and the results returned to X data
register.
0100 => Touch screen scan function: Y coordinate is converted and the results returned to Y data
register.
0101 => Touch screen scan function: Z1 and Z2 coordinates are converted and the results returned
to Z1 and Z2 data registers.
0110 => BAT1 input is converted and the result is returned to the BAT1 data register.
0111 => BAT2 input is converted and the result is returned to the BAT2 data register.
1000 => AUX input is converted and the result is returned to the AUX data register.
1001 => Scan function :AUX input is converted and the result is returned to the AUX data register.
Scan continues until stop bit is sent.
1010 => TEMP1 is converted and the result is returned to the TEMP1 data register.
1011 => Port scan function: BAT1, BAT2 and AUX inputs are measured and the results returned to
the appropriate data registers.
1100 => TEMP2 is converted and the result is returned to the TEMP2 data register.
1101 => Turn on X+, X− drivers
1110 => Turn on Y+, Y− drivers
1111 => Turn on Y+, X− drivers
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BIT
NAME
RESET VALUE
FUNCTION
D9−D8
RESOL
00
Resolution Control. The A/D converter resolution is specified with these bits.
00 => 12−bit resolution
01 => 8−bit resolution
10 => 10−bit resolution
11 => 12−bit resolution
D7−D6
ADAVG
00
Converter Averaging Control. These two bits allow you to specify the number of averages the
converter performs selected by bit D0, which selects either mean filter or median filter.
Mean Filter
Median filter
00 => No average
No average
01 => 4−data average
5-data average
10 => 8−data average
9-data average
11 => 16−data average
15-data average
D5−D4
ADCR
00
Conversion Rate Control. These two bits specify the internal clock rate which the A/D converter uses
to perform a single conversion. These bits are the same whether reading or writing.
tconv + N ) 4
ƒ
INTCLK
where fINTCLK is the internal clock frequency. For example, with 12 bit resolution and a 2-MHz
internal clock frequency, the conversion time is 8.0 µs. This yields an effective throughput rate of
125 kHz.
00 => 8-MHz internal clock rate (use for 8-bit resolution only)
01 => 4-MHz internal clock rate (use for 8-bit/10-bit resolution only)
10 => 2-MHz internal clock rate
11 => 1-MHz internal clock rate
D3−D1
PVSTC
000
D0
AVGFS
0
Panel Voltage Stabilization Time Control. These bits allow you to specify a delay time from the time
the touch screen drivers are enabled to the time the voltage is sampled and a conversion is started.
This allows the user to adjust for the settling of the individual touch panel and external capacitances.
000 => 0-µs stabilization time
001 => 100-µs stabilization time
010 => 500-µs stabilization time
011 => 1-ms stabilization time
100 => 5-ms stabilization time
101 => 10-ms stabilization time
110 => 50-ms stabilization time
111 => 100-ms stabilization time
Average Filter select
0 => Mean filter
1 => Median filter
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REGISTER 01H: Status Register
BIT
NAME
D15−D14 PINTDAV
READ/
WRITE
RESET
VALUE
R/W
10
Pen Interrupt or Data Available. These two bits program the function of the PINTDAV pin.
00 => Acts as PEN interrupt (Active Low) only. When PEN touch is detected, PINTDAV goes low.
01 => Acts as data available (Active Low) only. The PINTDAV goes low as soon as one set of ADC
conversion is completed. For scan mode, PINTDAV remains low as long as all the
appropriate registers have not been read out.
10 => Acts as both PEN interrupt and data available. When PEN touch is detected, PINTDAV goes
low. PINTDAV goes high once all the selected conversions are over.
11 => Same as 10
FUNCTION
D13
PWRDN
R
0
TSC−ADC Power down status
0 => TSC−ADC is active
1 => TSC−ADC stops conversion and powers down
D12
HCTLM
R
0
Host Controlled Mode Status
0 => Host controlled mode
1 => Self (TSC2100) controlled mode
D11
DAVAIL
R
0
Data Available Status
0 => No data available.
1 => Data is available(i.e. one set of conversion is done)
Note:− This bit gets cleared only after all the converted data have been completely read out.
D10
XSTAT
R
0
X Data Register Status
0 => No new data is available in X−data register
1 => New data for X−coordinate is available in register
Note: This bit gets cleared only after the converted data of X coordinate has been completely read
out of the register.
D9
YSTAT
R
0
Y Data Register Status
0 => No new data is available in Y−data register
1 => New data for Y−coordinate is available in register
Note: This bit gets cleared only after the converted data of Y coordinate has been completely read
out of the register.
D8
Z1STAT
R
0
Z1 Data Register Status
0 => No new data is available in Z1−data register
1 => New data is available in Z1−data register
Note: This bit gets cleared only after the converted data of Z1 coordinate has been completely read
out of the register.
D7
Z2STAT
R
0
Z2 Data Register Status
0 => No new data is available in Z2−data register
1 => New data is available in Z2−data register
Note: This bit gets cleared only after the converted data of Z2 coordinate has been completely read
out of the register.
D6
B1STAT
R
0
BAT1 Data Register Status
0 => No new data is available in BAT1−data register
1 => New data is available in BAT1−data register
Note: This bit gets cleared only after the converted data of BAT1 has been completely read out of
the register.
D5
B2STAT
R
0
BAT2 Data Register Status
0 => No new data is available in BAT2−data register
1 => New data is available in BAT2−data register
Note: This bit gets cleared only after the converted data of BAT2 has been completely read out of
the register.
D4
AXSTAT
R
0
AUX Data Register Status
0 => No new data is available in AUX−data register
1 => New data is available in AUX−data register
Note: This bit gets cleared only after the converted data of AUX has been completely read out of the
register.
D3
42
R
0
Reserved
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SLAS378− NOVEMBER 2003
BIT
NAME
READ/
WRITE
RESET
VALUE
D2
T1STAT
R
0
FUNCTION
TEMP1 Data Register Status
0 => No new data is available in TEMP1−data register
1 => New data is available in TEMP1−data register
Note: This bit gets cleared only after the converted data of TEMP1 has been completely read out of
the register.
D1
T2STAT
R
0
TEMP2 Data Register Status
0 => No new data is available in TEMP2−data register
1 => New data is available in TEMP2−data register
Note: This bit gets cleared only after the converted data of TEMP2 has been completely read out of
the register.
D0
R
0
Reserved
REGISTER 02H: Reserved
BIT
NAME
D15−D0
READ/
WRITE
RESET
VALUE
R
FFFFH
FUNCTION
Reserved
REGISTER 03H: Reference Control
NAME
READ/
WRITE
RESET
VALUE
R
000H
D4
VREFM
R/W
0
Voltage Reference Mode. This bit configures the VREF pin as either external reference or internal
reference.
0 => External reference
1 => Internal reference
D3−D2
RPWUDL
R/W
00
Reference Power Up Delay. These bits allow for a delay time for measurements to be made after
the reference powers up, thereby assuring that the reference has settled
00 => 0 µs
01 => 100 µs
10 => 500 µs
11 => 1000 µs
Note: This is valid only when the device is programmed for internal reference and Bit D1 = 1, i.e.,
reference is powered down between the conversions if not required.
D1
RPWDN
R/W
1
Reference Power Down. This bit controls the power down of the internal reference voltage.
0 => Powered up at all times.
1 => Powered down between conversions.
Note: when D4 = 0, i.e. device is in external reference mode, then the internal reference is powered
down always.
D0
IREFV
R/W
0
Internal Reference Voltage. This bit selects the internal voltage reference level for the TSC ADC.
0 => VREF = 1.25 V
1 => VREF = 2.50 V
BIT
D15−D5
FUNCTION
Reserved
REGISTER 04H: Reset Control
BIT
NAME
READ/
WRITE
RESET
VALUE
D15−D0
RSALL
R/W
FFFFH
FUNCTION
Reset All. Writing the code 0xBB00, as shown below, to this register causes the TSC2100 to reset
all its registers to their default, power−up values.
1011101100000000 => Reset all registers
Others
=> Do not write other sequences to this register.
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REGISTER 05H: Configuration Control
BIT
NAME
D15−D6
READ/
WRITE
RESET
VALUE
R
000H
FUNCTION
Reserved. Only write zeros to these bits.
D5−D3
PRECTM
R/W
000
Precharge Time. These bits set the amount of time allowed for precharging any pin capacitance on
the touch screen prior to sensing if a screen touch is happening.
000 => 20 µs
001 => 84 µs
010 => 276 µs
011 => 340 µs
100 => 1.044 ms
101 => 1.108 ms
110 => 1.300 ms
111 => 1.364 ms
D2−D0
RPWUDL
R/W
000
Sense Time. These bits set the amount of time the TSC2100 waits to sense whether the screen is
being touched, when converting a coordinate value.
000 => 32 µs
001 => 96 µs
010 => 544 µs
011 => 608 µs
100 => 2.080 ms
101 => 2.144 ms
110 => 2.592 ms
111 => 2.656 ms
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PAGE 2 CONTROL REGISTER MAP
REGISTER 00H: Audio Control 1
BIT
NAME
READ/
WRITE
RESET
VALUE
D15−D14
ADCHPF
R/W
00
ADC High Pass Filter
00 => Disabled
01 => −3dB point = 0.0045*Fs
10 => −3dB point = 0.0125*Fs
11 => −3dB point = 0.025*Fs
Note: Fs is ADC sample rate
D13−D12
ADCIN
R/W
00
ADC Input Mux
00 => ADC Input = Single-ended input MIC
01 => ADC Input = Single-ended input AUX
10 => ADC Input = Differential input MICIN and AUX
11 => ADC Input = Differential input MICIN and AUX
D11−D10
WLEN
R/W
00
Codec Word Length
00 => Word length = 16 bit
01 => Word length = 20 bit
10 => Word length = 24 bit
11 => Word length = 32 bit
D9−D8
DATFM
R/W
00
Digital Data Format
00 => I2S mode
01 => DSP mode
10 => Right justified
11 => Left justified
Note: Right justified, valid only when the ratio between DAC and ADC sample rate is an integer.
e.g. ADC = 32 kHz and DAC = 24 kHz or vice-versa is invalid for right justified mode.
R
00
Reserved
D5−D3
DACFS
R/W
000
DAC Sampling Rate
000 => DAC FS = Fsref/1
001 => DAC FS = Fsref/(1.5)
010 => DAC FS = Fsref/2
011 => DAC FS = Fsref/3
100 => DAC FS = Fsref/4
101 => DAC FS = Fsref/5
110 => DAC FS = Fsref/5.5
111 => DAC FS = Fsref/6
Note: Fsref is set between 39 kHz or 53kHz
D2−D0
ADCFS
R/W
000
ADC Sampling Rate
000 => ADC FS = Fsref/1
001 => ADC FS = Fsref/(1.5)
010 => ADC FS = Fsref/2
011 => ADC FS = Fsref/3
100 => ADC FS = Fsref/4
101 => ADC FS = Fsref/5
110 => ADC FS = Fsref/5.5
111 => ADC FS = Fsref/6
Note: Fsref is set between 39 kHz or 53kHz
D7−D6
FUNCTION
45
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SLAS378− NOVEMBER 2003
REGISTER 01H: CODEC ADC Gain Control
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
ADMUT
R/W
1
FUNCTION
ADC Channel Mute
1 => ADC channel mute
0 => ADC channel not muted
Note: If AGC is enabled then D15−D8 reflects gain being applied by AGC.
If AGC is on the decoding for read values is as follows
01110111 => +59.5 dB
01110110 => +59.0 dB
−−−−−
00000000 => 0 dB
−−−−−
11101001 => −11.5 dB
11101000 => −12 dB
D14−D8
ADPGA
R/W
0000000
ADC PGA Settings
0000000 => ADC PGA = 0 dB
0000001 => ADC PGA = 0.5 dB
0000010 => ADC PGA = 1.0 dB
−−−−−
1110110 => ADC PGA = 59.0 dB
1110111 => ADC PGA = 59.5 dB
1111000 => ADC PGA = 59.5 dB
−−−−−
1111110 => ADC PGA = 59.5 dB
1111111 => ADC PGA = 59.5 dB
Note: If AGC is enabled then D15−D8 reflects gain being applied by AGC. If AGC is on,
the decoding for read values is as follows
01110111 => +59.5 dB
01110110 => +59.0 dB
−−−−−
00000000 => 0 dB
−−−−−
11101001 => −11.5 dB
11101000 => −12 dB
D7−D5
46
AGCTG
R/W
000
AGC Target Level. These three bits set the AGC’s targeted ADC output level.
000 => −5.5 dB
001 => −8.0 dB
010 => −10 dB
011 => −12 dB
100 => −14 dB
101 => −17 dB
110 => −20 dB
111 => −24 dB
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SLAS378− NOVEMBER 2003
BIT
NAME
READ/
WRITE
RESET
VALUE
D4−D1
AGCTC
R/W
0000
FUNCTION
AGC Time Constant. These four bits set the AGC attack and decay time constants.
Time constants remain the same irrespective of any sampling frequency.
Attack time (ms)
0000
8
0001
11
0010
16
0011
20
0100
8
0101
11
0110
16
0111
20
1000
8
1001
11
1010
16
1011
20
1100
8
1101
11
1110
16
1111
20
D0
AGCEN
R/W
0
AGC Enable
0 => AGC is off
1 => AGC is on
Decay time (ms)
100
100
100
100
200
200
200
200
400
400
400
400
500
500
500
500
(ADC PGA is controlled by D15−D8 ADC PGA Control)
(ADC PGA is controlled by AGC)
REGISTER 02H: CODEC DAC Gain Control
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
DALMU
R/W
1
D14−D8
DALVL
R/W
1111111
FUNCTION
DAC Left Channel Mute
1 => DAC left channel muted
0 => DAC left channel not muted
DAC Left Channel Volume Control
0000000 => DAC left channel volume control = 0 dB
0000001 => DAC left channel volume control = −0.5 dB
0000010 => DAC left channel volume control = −1.0 dB
−−−−−
1111110 => DAC left channel volume control = −63.0 dB
1111111 => DAC left channel volume control = −63.5 dB
D7
DARMU
R/W
1
D6−D0
DARVL
R/W
1111111
DAC Right Channel Mute
1 => DAC right channel muted
0 => DAC right channel not muted
DAC Right Channel Volume Control
0000000 => DAC right channel volume control = 0 dB
0000001 => DAC right channel volume control = −0.5 dB
0000010 => DAC right channel volume control = −1.0 dB
−−−−−
1111110 => DAC right channel volume control = −63.0 dB
1111111 => DAC right channel volume control = −63.5 dB
47
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REGISTER 03H: CODEC Sidetone Control
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
ASTMU
R/W
1
D14−D8
ASTG
R/W
1000101
FUNCTION
Analog Sidetone Mute Control
1 => Analog sidetone mute
0 => Analog sidetone not muted
Analog Sidetone Gain Setting
0000000 => Analog sidetone gain setting = −34.5dB
0000001 => Analog sidetone gain setting = −34dB
0000010 => Analog sidetone gain setting = −33.5dB
−−−−−
1000101 => Analog sidetone gain setting = 0dB
1000110 => Analog sidetone gain setting = 0.5dB
−−−−−
1011100 => Analog sidetone gain setting = 11.5dB
1011101 => Analog sidetone gain setting = 12dB
1011110 => Analog sidetone gain setting = 12dB
1011111 => Analog sidetone gain setting = 12dB
−−−−−
11xxxxx => Analog sidetone gain setting = 12dB
D7
DSTMU
R/W
1
D6−D1
DSTG
R/W
000000
Digital Sidetone Mute Control
1 => Digital sidetone muted
0 => Digital sidetone not muted
Digital Sidetone Setting
000000 => Digital sidetone gain = 0dB
000001 => Digital sidetone gain = −1.5dB
000010 => Digital sidetone gain = −3.0dB
−−−−−
1xxxxx => Digital sidetone gain = −48dB
Note: Digital sidetone setting applied at zero cross over
D0
ASTGF
R
0
Analog Sidetone PGA Flag ( Read Only )
0 => Gain applied /= PGA register setting
1 => PGA applied = PGA register setting.
Note: Analog sidetone gain is implemented at zero crossings of the signal.
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REGISTER 04H: Audio Control 2
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
KCLEN
R/W
0
D14−D12
KCLAC
R/W
100
FUNCTION
Keyclick Enable
0 => Keyclick disabled
1 => Keyclick enabled
Note: This bit is automatically cleared after giving out the keyclick signal length equal to the
programmed value.
Keyclick Amplitude Control
000 => Lowest amplitude
100 => Medium amplitude
111 => Highest amplitude
D11
APGASS
R/W
0
ADC Channel PGA Soft-stepping control
0 => 0.5dB change every ADWS
1 => 0.5dB change every 2 ADWS
Note: When AGC is enabled, this bit is read only. The read values indicate the following
0 => signal power greater than noise threshold
1 => signal power is less than noise threshold
D10−D8
KCLFRQ
R/W
100
Keyclick Frequency
000 => 62.5Hz
001 => 125Hz
010 => 250Hz
011 => 500Hz
100 => 1kHz
101 => 2kHz
110 => 4kHz
111 => 8kHz
D7−D4
KCLLN
R/W
0001
Keyclick Length
0000 => 2 periods key click
0001 => 4 periods key click
0010 => 6 periods key click
−−−−−
1110 => 30 periods key click
1111 => 32 periods key click
D3
DLGAF
R
0
DAC Left Channel PGA Flag ( Read Only )
0 => Gain applied /= PGA register setting
1 => Gain applied = PGA register setting.
Note: This flag indicates when the soft-stepping for DAC left channel is completed
D2
DRGAF
R
0
DAC Right Channel PGA Flag ( Read Only )
0 => Gain applied /= PGA register setting
1 => Gain applied = PGA register setting.
Note: This flag indicates when the soft-stepping for DAC right channel is completed
D1
DASTC
R/W
0
DAC Channel PGA Soft-stepping control
0 => 0.5dB change every LRCK
1 => 0.5dB change every 2 LRCK
D0
ADGAF
R
0
ADC Channel PGA Flag ( Read Only )
1 => Gain applied = PGA register setting.
0 => Gain applied /= PGA register setting
Note: This flag indicates when the soft-stepping for ADC channel is completed. When AGC is
enabled the read value of this bit indicates the following
0 => AGC is not saturated.
1 => AGC is saturated.
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REGISTER 05H: CODEC Power Control
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
PWDNC
R/W
1
Codec Power-Down Control
0 => Codec powered up
1 => Codec powered down
R
0
Reserved (During read the value of this bit is 0. Write only 0 into this location.)
D13
ASTPWD
R/W
1
Analog Sidetone Power-down Control
0 => Analog sidetone powered up
1 => Analog sidetone powered down
D12
DAODRC
R/W
0
Audio Output Driver Control
0 => Output driver in low power mode.
1 => Output driver in high power mode.
D11
ASTPWF
R
1
Analog Sidetone Power-Down Flag
0 => Analog sidetone powered down is not complete.
1 => Analog sidetone powered down is complete.
D10
DAPWDN
R/W
1
DAC Power-Down Control
0 => Power up the DAC
1 => Power down the DAC
D9
ADPWDN
R/W
1
ADC Power-Down Control
0 => Power up the ADC
1 => Power down the ADC
D8
VGPWDN
R/W
1
Driver Virtual Ground Power Down
0 => Power up the VGND amp
1 => Power down the VGND amp
D7
ADPWDF
R
1
ADC Power-Down Flag
0 => ADC power down is not complete
1 => ADC power down is complete
D6
DAPWDF
R
1
DAC Power-Down Flag (See DAC Powerdown section of this data sheet)
0 => DAC power down is not complete
1 => DAC power down is complete
D5
ADWSF
R/W
0
ADWS Pin Function
0 => ADWS pin acts as hardware power down.
1 => ADWS pin acts as ADC Word−Select.
D14
FUNCTION
Note: ADWS pin should be programmed as hardware power down only if the ADC channel is
powered down or both the ADC and DAC channels have the same sampling rate. If both the ADC
and DAC channels have the same sampling rates then LRCK can act as a common word select
signal for the ADC and DAC.
D4
VBIAS
D3−D2
50
R/W
0
VBIAS voltage
0 => VBIAS output = 2.5 V
1 => VBIAS output = 2.0 V
R
00
Reserved Write only 00 into this location.
D1
EFFCTL
R/W
0
Digital Audio Effects Filter Control
0 => Disable digital audio effects filter
1 => Enable digital audio effects filter
D0
DEEMPF
R/W
0
De−Emphasis Filter Enable
0 => Disable de-emphasis filter
1 => Enable de-emphasis filter
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REGISTER 06H: Audio Control 3
BIT
NAME
READ/
WRITE
RESET
VALUE
D15−D14
DMSVOL
R/W
00
DAC Channel Master Volume Control
00 => Left channel and right channel have independent volume controls
01 => Left channel volume control is the programmed value of the right channel volume control.
10 => Right channel volume control is the programmed value of the left channel volume control.
11 => same as 00
D13
REFFS
R/W
0
Reference Sampling Rate. This setting controls the coefficients in the de-emphasis filter, the
time-constants in AGC, and internal divider values that generate a clock for the touch
screen/measurement ADC. If an Fsref above 48 kHz is being used, then it is recommended to
set this to the 48-kHz setting, otherwise either setting can be used.
0 => Fsref = 48.0 kHz
1 => Fsref = 44.1 kHz
D12
DAXFM
R/W
0
Master Transfer Mode
0 => Continuous data transfer mode
1 => 256−s data transfer mode
D11
SLVMS
R/W
0
CODEC Master Slave Selection
0 => TSC2100 is slave codec
1 => TSC2100 is master codec
D10−D9
DAPK2PK
R/W
00
D8
ADCOVF
R
0
DAC Max Output Signal Swing and Common Mode Voltage
00 => DAC max output signal swing = 2.0 V, VCM = 1.35 V
01 => DAC max output signal swing = 2.192 V (only recommended for analog supply of 3.0 V
and digital supply of 1.65 V and above), VCM = 1.48 V
10 => DAC max output signal swing = 2.402 V (only recommended for analog supply of 3.3 V
and digital supply of 1.8 V and above), VCM = 1.62 V
11 => DAC max output signal swing = 2.633 V (only recommended for analog supply of 3.6 V
and digital supply of 1.95 V), VCM = 1.78 V
ADC Channel Overflow Flag ( Read Only )
0 => ADC channel data is within saturation limits
1 => ADC channel data has exceeded saturation limits.
Note : This flag is reset only on register read.
D7
DALOVF
R
0
DAC Left Channel Overflow Flag ( Read Only )
0 => DAC left channel data is within saturation limits
1 => DAC left channel data has exceeded saturation limits
Note : This flag is reset only on register read.
D6
DAROVF
R
0
DAC Right Channel Overflow Flag ( Read Only )
0 => DAC right channel data is within saturation limits
1 => DAC right channel data has exceeded saturation limits
Note : This flag is reset only on register read.
D5−D4
AGCNL
R/W
00
AGC Noise Threshold.
00 => −60 dB
01 => −70 dB
10 => −80 dB
11 => −90 dB
FUNCTION
Note: AGC does not try to achieve the programmed ADC output levels if the input signal is below
the programmed noise thresholds. This feature helps to avoid gaining up noise during silence
periods.
D3
CLPST
R/W
0
D2−D0
REVID
R
XXX
AGC Clip Stepping Enable
0 => Not enabled
1 => Enabled
Reserved
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REGISTER 07H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N0
R/W
27619
FUNCTION
Left channel digital audio effects filter coefficient N0.
REGISTER 08H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N1
R/W
−27034
FUNCTION
Left channel digital audio effects filter coefficient N1.
REGISTER 09H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N2
R/W
26461
FUNCTION
Left channel digital audio effects filter coefficient N2.
REGISTER 0AH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N3
R/W
27619
FUNCTION
Left channel digital audio effects filter-coefficient N3.
REGISTER 0BH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N4
R/W
−27034
FUNCTION
Left channel digital audio effects filter-coefficient N4.
REGISTER 0CH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_N5
R/W
26461
FUNCTION
Left channel digital audio effects filter-coefficient N5.
REGISTER 0DH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_D1
R/W
32131
FUNCTION
Left channel digital audio effects filter-coefficient D1.
REGISTER 0EH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_D2
R/W
−31506
FUNCTION
Left channel digital audio effects filter-coefficient D2.
REGISTER 0FH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_D4
R/W
32131
FUNCTION
Left channel digital audio effects filter-coefficient D4.
REGISTER 10H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
L_D5
R/W
−31506
FUNCTION
Left channel digital audio effects filter-coefficient D5.
REGISTER 11H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N0
R/W
27619
FUNCTION
Right channel digital audio effects filter-coefficient N0.
REGISTER 12H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N1
R/W
−27034
52
FUNCTION
Right channel digital audio effects filter-coefficient N1.
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REGISTER 13H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N2
R/W
26461
FUNCTION
Right channel digital audio effects filter-coefficient N2.
REGISTER 14H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N3
R/W
27619
FUNCTION
Right channel digital audio effects filter-coefficient N3.
REGISTER 15H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N4
R/W
−27034
FUNCTION
Right channel digital audio effects filter-coefficient N4.
REGISTER 16H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_N5
R/W
26461
FUNCTION
Right channel digital audio effects filter-coefficient N5.
REGISTER 17H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_D1
R/W
32131
FUNCTION
Right channel digital audio effects filter-coefficient D1.
REGISTER 18H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_D2
R/W
−31506
FUNCTION
Right channel digital audio effects filter-coefficient D2.
REGISTER 19H: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_D4
R/W
32131
FUNCTION
Right channel digital audio effects filter coefficient D4.
REGISTER 1AH: Digital Audio Effects Filter Coefficients
BIT
NAME
READ/
WRITE
RESET VALUE
(IN DECIMAL)
D15−D0
R_D5
R/W
−31506
FUNCTION
Right channel digital audio effects filter coefficient D5.
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REGISTER 1BH: PLL Programmability
BIT
NAME
READ/
WRITE
RESET VALUE
D15
PLLSEL
R/W
0
D14−D11
QVAL
R/W
0010
FUNCTION
PLL Enable
0 => Disable PLL
1 => Enable PLL
Q value. Valid only if PLL is disabled.
0000 => 16
0001 => 17
0010 => 2
0011 => 3
−−−−−
1100 => 12
1101 => 13
1110 => 14
1111 => 15
D10−D8
PVAL
R/W
000
P value. Valid when PLL is enabled
000 => 8
001 => 1
010 => 2
011 => 3
100 => 4
101 => 5
110 => 6
111 => 7
D7−D2
JVAL
R/W
000001
J value. Valid only if PLL is enabled.
000000 => Not valid
000001 => 1
000010 => 2
−−−−−
111110 => 62
111111 => 63
D1−D0
Reserved
R
00
Reserved (write only 00)
REGISTER 1CH: PLL Programmability
BIT
NAME
READ/
WRITE
RESET VALUE
D15−D2
DVAL
R/W
0 (in decimal)
D1−D0
Reserved
R
00
54
FUNCTION
D value. Used when PLL is enabled.
D value is valid from 0000 to 9999 in decimal.
Programmed value greater than 9999 is treated as 9999
00000000000000 => 0 decimal
00000000000001 => 1 decimal
Reserved (write only 00)
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REGISTER 1DH: Audio Control 4
BIT
NAME
READ/
WRITE
RESET
VALUE
D15
ASTPD
R/W
0
ADC PGA Soft-Stepping Control
0 => Soft-stepping enabled
1 => Soft-stepping disabled
D14
DASTPD
R/W
0
DAC PGA Soft-Stepping Control
0 => Soft-stepping enabled
1 => Soft-stepping disabled
D13
ASSTPD
R/W
0
Analog Sidetone Soft-Stepping Control
0 => Soft-stepping enabled
1 => Soft-stepping disabled
D12
DSTPD
R/W
0
Digital Sidetone Zero Cross Control
0 => Zero cross enabled
1 => Zero cross disabled
D11
Reserved
R
0
Reserved
D10−D9
AGC_HYST
R/W
00
AGC Hysteresis Control
00 =>1 dB hysteresis
01 => 2 dB hysteresis
10 => 4 dB hysteresis
11 => No hysteresis
D8
SHCKT_DIS
R/W
0
Disable Short Circuit Detection
0 => Short circuit detection enabled
1 => Short circuit detection disabled
D7
SHCKT_PD
R/W
0
Power down drivers if Short Circuit Detected
0 => No auto power down of drivers on short circuit.
1 => Auto power down drivers on short circuit.
D6
SHCKT_FLAG
R
0
Short Circuit Detected Flag
0 => Short circuit not detected
1 => Short circuit detected
D5
DAC_POP_RED
R
0
DAC POP Reduction Enable
0 => Disable POP reduction
1 => Enable POP reduction
D4
DAC_POP_RED_
SET1
R/W
0
DAC POP reduction setting 1
0 => Fast setting
1 => Slow setting
D3−D2
DAC_POP_RED_
SET2
R/W
00
DAC POP reduction setting 2
00 => Long setting
11 => Short setting
D1−D0
PGID
R
XX
FUNCTION
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REGISTER 1EH: Audio Control 5
BIT
NAME
READ/
WRITE
RESET
VALUE
D15−D9
MAX_AGC_PGA
R/W
1111111
D8−D6
AGC_NOI_DEB
R/W
000
AGC Debounce time for speech mode to silence mode transition
000 => 0 ms
001 => 0.5 ms
010 => 1.0 ms
−−−−−
110 => 16.0 ms
111 => 32.0 ms
D5−D3
AGC_SIG_DEB
R/W
000
AGC Debounce time for silence mode to speech mode transition
000 => 0 ms
001 => 0.5 ms
010 => 1.0 ms
−−−−−
110 => 16.0 ms
111 => 32.0 ms
D2
DRV_POP_DIS
R/W
0
Audio Output Driver POP reduction enable
0 => Enabled
1 => Disabled
D1
DRV_POP_LEN
R/W
0
Audio Output Driver POP reduction duration
0 => Output driver ramps to final voltage in approximately 1 msec, if VGND is
powered (0.8 sec otherwise)
1 => Output driver ramps to final voltage in approximately 5 msec, if VGND is
powered (4 sec otherwise)
D0
Reserved
R
0
Reserved. Do not write 1 to this location.
FUNCTION
MAX ADC PGA applicable for AGC
0000000 => 0 dB
0000001 => 0.5 dB
0000010 => 1.0 dB
−−−−−
1110110 => 59.0 dB
1110111 => 59.5 dB
1111000 => 59.5 dB
−−−−−
1111111 => 59.5 dB
LAYOUT
The following layout suggestions should provide optimum performance from the TSC2100. However, many portable
applications have conflicting requirements concerning power, cost, size, and weight. In general, most portable devices
have fairly clean power and grounds because most of the internal components are very low power. This situation means
less bypassing for the converter power and less concern regarding grounding. Still, each situation is unique and the
following suggestions should be reviewed carefully.
For optimum performance, care must be taken with the physical layout of the TSC2100 circuitry. The basic SAR architecture
is sensitive to glitches or sudden changes on the power supply, reference, ground connections, and digital inputs that occur
just prior to latching the output of the analog comparator. Therefore, during any single conversion for an n-bit SAR converter,
there are n windows in which large external transient voltages can easily affect the conversion result. Such glitches might
originate from switching power supplies, nearby digital logic, and high power devices. The degree of error in the digital
output depends on the reference voltage, layout, and the exact timing of the external event. The error can change if the
external event changes in time with respect to the timing of the critical n windows.
With this in mind, power to the TSC2100 must be clean and well bypassed. A 0.1-µF ceramic bypass capacitor must be
placed as close to the device as possible. A 1-µF to 10-µF capacitor may also be needed if the impedance between the
TSC2100 supply pins and the system power supply is high.
A bypass capacitor on the VREF pin is generally not needed because the reference is buffered by an internal op-amp,
although it can be useful to reduce reference noise level. If an external reference voltage originates from an op-amp, make
sure that it can drive any bypass capacitor that is used without oscillation.
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The TSC2100 architecture offers no inherent rejection of noise or voltage variation in regards to using an external reference
input. This is of particular concern when the reference input is tied to the power supply. Any noise and ripple from the supply
appears directly in the digital results. While high frequency noise can be filtered out, voltage variation due to line frequency
(50 Hz or 60 Hz) can be difficult to remove.
The ground pins must be connected to a clean ground point. In many cases, this is the analog ground. Avoid connections
which are too near the grounding point of a microcontroller or digital signal processor. If needed, run a ground trace directly
from the converter to the power supply entry or battery connection point. The ideal layout includes an analog ground plane
dedicated to the converter and associated analog circuitry.
In the specific case of use with a resistive touch screen, care must be taken with the connection between the converter
and the touch screen. Since resistive touch screens have fairly low resistance, the interconnection must be as short and
robust as possible. Loose connections can be a source of error when the contact resistance changes with flexing or
vibrations.
As indicated previously, noise can be a major source of error in touch-screen applications (e.g., applications that require
a back-lit LCD panel). This EMI noise can be coupled through the LCD panel to the touch screen and cause flickering of
the converted ADC data. Several things can be done to reduce this error, such as utilizing a touch screen with a bottom-side
metal layer connected to ground. This couples the majority of noise to ground. Additionally, filtering capacitors, from Y+,
Y–, X+, and X– to ground, can also help. Note, however, that the use of these capacitors increases screen settling time
and requires longer panel voltage stabilization times, as well as increased precharge and sense times for the PINTDAV
circuitry of the TSC2100.
CONVERSION TIME CALAULATIONS FOR THE TSC2100
Touch Screen Conversion Initiated At Touch Detect
The time needed to get a converted X/Y coordinate for reading can be calculated by (not including the time needed to send
the command over the SPI bus):
t
coordinate
+2
t
ȱǒtPRE ) tSNS ) tPVSǓȳ
ȧ
ȧ
125 ns
Ȳ
ȴ
OSC
) 18
t
OSC
) n2
t
OSC
t
OSC
)2
) n3
t
NJ ƪǒ
N
AVG
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
OSC
where:
tcoordinate = time to convert X/Y coordinate
tPVS = Panel voltage stabilization time
tPRE = precharge time
tSNS = sense time
NAVG = number of averages; for no averaging, NAVG = 1
NBITS = number of bits of resolution
ƒconv = A/D converter clock frequency
tOSC = Oscillator clock period
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 4 ; if tPVS = 0 µs
0 ; if tPVS ≠ 0 µs
n3 = 0 ; if tSNS = 32 µs
2 ; if tSNS ≠ 32 µs
NOTE: The above formula is exactly valid only when the codec is powered down. Also, after touch detect, the formula holds true from second
conversion onwards.
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Programmed
for Self
Controlled
X−Y Scan
Mode
Reading
X−Data
Register
SS DEACTIVATED
Sample,Conversion &
Averaging for
Y−Coordinate
Detecting Touch
Sample,Conversion &
Averaging for
X−Coordinate
Detecting
Touch
Detecting
Touch
Reading
Y−Data
Register
Sample,Conversion &
Averaging for
Y−Coordinate
Detecting
Touch
Touch Is Detected
PINTDAV
Touch Is Detected
(As PENIRQ
[D15−D14 = 00])
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
PINTDAV
(As PENIRQ & DATA_AVA
[D15−D14 = 10/11])
Touch Is Detected
The time for a complete X/Y/Z1/Z2 coordinate conversion is given by(not including the time needed to send the command
over the SPI bus):
t
coordinate
+3
t
ȱǒtPRE ) tSNS ) tPVSǓȳ
ȧ
ȧ
125 ns
Ȳ
ȴ
OSC
) 33
t
OSC
) n2
t
OSC
t
OSC
)4
) n3
t
NJ ƪǒ
N
AVG
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
OSC
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 4 ; if tPVS = 0 µs
0 ; if tPVS ≠ 0 µs
n3 = 0 ; if tSNS = 32 µs
3 ; if tSNS ≠ 32 µs
NOTE: The above formula is exactly valid only when the codec is powered down. Also after touch detect the formula holds true from second
conversion onwards.
Programmed
for Self
Controlled
X−Y−Z1−Z2
Scan
Mode
Detecting Touch
Reading
X−Data
Register
SS DEACTIVATED
Sample,Conversion & Detecting
Averaging for
Touch
Y−Coordinate
Touch Is Detected
Sample,Conversion & Detecting
Averaging for
Touch
X−Coordinate
Touch is Detected
Sample,Conversion &
Detecting
Averaging for
Touch
Z1−Coordinate & Z2−Coordinate
Reading Reading Reading
Y−Data Z1−Data Z2−Data
Register Register Register
Sample,Conversion &
Averaging for
Y−Coordinate
Detecting
Touch
Touch is Detected
PINTDAV
(As PENIRQ
[D15−D14 = 00])
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
PINTDAV
(As PENIRQ & DATA_AVA
[D15−D14 = 10/11])
Touch Is Detected
NOTE: If the PINTDAV signal is programmed to be used for pen-interrupt by setting bits D15−D14 of REG01H/Page−2 to either 00, 01, or 11, then
the high duration of PINTDAV is given by:
ǒtPRE ) tSNSǓ
125 ns
58
t
OSC
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SLAS378− NOVEMBER 2003
Touch Screen Conversion Initiated by the Host
The time needed to convert any single coordinate either X or Y under host control (not including the time needed to send
the command over the SPI bus) is given by:
t
coordinate
ȱǒtPVSǓȳ
ȧ125 nsȧ
Ȳ
ȴ
+
t
OSC
t
) 14
OSC
t
NJ ƪǒ
) N
OSC
AVG
) n2
t
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
OSC
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 2 ; if tPVS = 0 µs
0 ; if tPVS ≠ 0 µs
REG−00 of
PAGE−01
Is Updated
for
X Scan
Mode
Programmed
for Host
Controlled
Mode
Detecting Touch
Reading
X−Data
Register
SS DEACTIVATED
Sample,Conversion &
Averaging for
X−Coordinate
Waiting for Host to Write
into REG−00 of PAGE−01
Detecting
Touch
Waiting for Host to Write Into
REG−00 of PAGE−01
Touch Is Detected
PINTDAV
(As PENIRQ
[D15−D14 = 00])
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
Touch Is Still There
PINTDAV
(As PENIRQ & DATA_AVA
[D15−D14 = 10/11])
The time needed to convert the Z coordinate under host control (not including the time needed to send the command over
the SPI bus) is given by:
t
coordinate
ȱǒtPVSǓȳ
ȧ125 nsȧ
Ȳ
ȴ
+
t
OSC
) 20
t
OSC
t
)2
OSC
) n2
NJ ƪǒ
N
AVG
t
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
OSC
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 2 ; if tPVS = 0 µs
0 ; if tPVS ≠ 0 µs
59
www.ti.com
SLAS378− NOVEMBER 2003
REG−00 of
PAGE−01
Is Updated
for
Z1−Z2 Scan
Mode
Programmed
for Host
Controlled
Mode
Waiting for Host to Write
into REG−00 of PAGE−01
Detecting Touch
Reading
Z1−Data
Register
SS DEACTIVATED
Sample,Conversion &
Averaging for
Z1−Coordinate & Z2−Coordinate
Reading
Z2−Data
Register
Detecting
Touch
Waiting for Host to Write Into
REG−00 of PAGE−01
Touch Is Detected
PINTDAV
(As PENIRQ
[D15−D14 = 00])
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
PINTDAV
(As PENIRQ & DATA_AVA
[D15−D14 = 10/11])
REG−00 of
PAGE−01
Is Updated
for
X−Y Scan
Mode
Programmed
for Host
Controlled
Mode
Detecting Touch
Waiting for Host to
Write into REG−00 of
PAGE−01
Touch Is Still There
Reading
X−Data
Register
SS DEACTIVATED
Sample,Conversion &
Averaging for
Y−Coordinate
Sample,Conversion &
Averaging for
X−Coordinate
Detecting
Touch
Detecting
Touch
Reading
Y−Data
Register
Sample,Conversion &
Averaging for
Y−Coordinate
Detecting
Touch
Touch Is Detected
PINTDAV
Touch Is Detected
(As PENIRQ
[D15−D14 = 00])
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
PINTDAV
(As PENIRQ & DATA_AVA
[D15−D14 = 10/11])
Touch Is Detected
NOTE: If the PINTDAV signal is programmed to be used for pen-interrupt by setting bits D15−D14 of REG01H/Page−2 to either 00, 01, or 11, then
the high duration of PINTDAV is given by:
ǒtPRE ) tSNSǓ
t
OSC
125 ns
Non-Touch Screen Measurement Operation
The time needed to make temperature, auxiliary, or battery measurements is given by:
t+
NJ ƪǒ
N
AVG
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) n ) 1
1
2
ƒ conv
t
OSC
) 15
t
OSC
) n3
t
OSC
where:
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 24 ; if measurement is for TEMP1 case
12 ; if measurement is for other than TEMP1 case
n3 = 0 ; if external reference mode is selected
3 ; if tREF = 0 µs or reference is programmed for power up all the time.
1 + tREF /125 ns; if tREF ≠ 0 µs and reference needs to power down between conversions.
tREF is the reference power up delay time.
60
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SLAS378− NOVEMBER 2003
REG−00 of
PAGE−01
Is Updated
for
BAT1 Scan
Mode
Programmed for
Host Controlled
Mode With Invalid
A/D Function
Selected
Waiting for Host to Write
into REG−00 of PAGE−01
Detecting Touch
Reading
BAT1−Data
Register
SS DEACTIVATED
Wait for Reference Power-Up Delay in Case
of Internal Ref Mode if Applicable
Sample,Conversion &
Averaging for
BAT1 input
Waiting for Host to
Write into REG−00
of PAGE−01
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
The time needed for continuous AUX conversion in scan mode is given by:
t+
NJ ƪǒ
N
AVG
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
t
OSC
)8
t
OSC
where:
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
NOTE: The above equation is valid only from second conversion onwards.
Programmed for
Host Controlled
Mode With Invalid
A/D Function
Selected
REG−00 of
PAGE−01
Is Updated
for Continous
AUX SCAN
Mode
Detecting Touch
Waiting for Host to
Write into REG−00
of PAGE−01
Reading
AUX−Data
Register
SS DEACTIVATED
Wait for Reference Power-Up Delay in Case
of Internal Ref Mode if Applicable
Sample,Conversion &
Averaging for
AUX input
Reading
AUX−Data
Register
Sample,Conversion &
Averaging for
AUX input
Sample,Conversion &
Averaging for
AUX input
PINTDAV
(As DATA_AVA
[D15−D14 = 01])
Port Scan Operation
The time needed to complete one set of port scan conversions is given by:
t+3
NJ ƪǒ
N
AVG
N
BITS
Ǔ
)1
ƫ Nj
8 MHz ) n ) 12 ) 1
1
ƒ conv
t
OSC
) 31
t
OSC
) n2
t
OSC
where:
n1 = 6 ; if ƒconv = 8 MHz
7 ; if ƒconv ≠ 8 MHz
n2 = 0 ; if external reference mode is selected
3 ; if tREF = 0 µs or reference is programmed for power up all the times.
1 + tREF /125 ns; if tREF ≠ 0 µs and reference needs to power down between conversions.
tREF is the reference power up delay time.
61
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SLAS378− NOVEMBER 2003
AUDIO CODEC FILTER FREQUENCY RESPONSES
Pass-Band Frequency Response of ADC Digital Filter
Frequency Response of Full ADC Channel Digital Filter at Fs = 48 kHz
0.02
0
Magnitude − dB
−0.02
−0.04
−0.06
−0.06
−0.1
−0.12
−0.14
−0.16
−0.18
0.2
0.4
0.6
0.8
1
1.2
Frequency − Hz
1.4
1.6
1.8
x 104
Frequency Response of ADC High-Pass Filter (Fcut-off = 0.0045 Fs)
Frequency Response of ADC HPF at Fs = 48 kHz With −3 dB at 0.0045 Fs
0
−2
Magnitude − dB
−4
−6
−8
−10
−12
−14
0
62
500
1000
1500 2000 2500 3000 3500 4000
Frequency − Hz
4500
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SLAS378− NOVEMBER 2003
Frequency Response of ADC High-Pass Filter (Fcut-off = 0.0125 Fs)
Frequency Response of ADC HPF at Fs = −48 kHz With −3 dB at 0.0125 Fs
0
−2
−4
Magnitude − dB
−6
−8
−10
−12
−14
−16
−18
0
1000
2000
3000
4000
Frequency − Hz
5000
6000
Frequency Response of ADC High-Pass Filter (Fcut-off = 0.025 Fs)
Frequency Response of ADC HPF at Fs = 48 kHz With −3 dB at 0.025 Fs
0
−2
−4
Magnitude − dB
−6
−8
−10
−12
−14
−16
−18
0
1000 2000 3000 4000 5000 6000 7000 8000
Frequency − Hz
9000
63
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SLAS378− NOVEMBER 2003
DAC CHANNEL DIGITAL FILTER
DAC Channel Digital Filter Frequency Response
Frequency Response of Full DAC Channel Digital Filterat Fs = 48 kHz
0
−20
Magnitude − dB
−40
−60
−80
−100
−120
−140
−160
0
0.5
1
1.5
2
Frequency − Hz
2.5
3
3.5
x 105
DAC Channel Digital Filter Pass-Band Frequency Response
Frequency Response of Full DAC Channel Digital Filter at Fs = 48 kHz
0.04
0.02
Magnitude − dB
0
−0.02
−0.04
−0.06
−0.08
−0.1
−0.12
−0.14
0.5
64
1
1.5
Frequency − Hz
2
x 104
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SLAS378− NOVEMBER 2003
DEFAULT DIGITAL AUDIO EFFECTS FILTER RESPONSE AT 48 ksps
Frequency Response of 4th Order Effects Filter With Default Coefficients Set
0
Magnitude − dB
−0.5
−1
−1.5
−2
−2.5
−3
100
101
102
103
Frequency − Hz
104
DE-EMPHASIS FILTER FREQUENCY RESPONSE
De-Emphasis Filter Response at 32 ksps
Digital De-Emphasis Frequency Response at Fs = 32 kHz
0
−1
−2
Gain − dB
−3
−4
−5
−6
−7
−8
−9
−10
0
2000
4000
6000
8000 10000 12000 14000 16000
Frequency − Hz
65
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SLAS378− NOVEMBER 2003
De-Emphasis Error at 32 ksps
De-Emphasis Error With Respect to Ideal Frequency Response For Fs = 33 kHz
0.3
0.25
0.2
Gain − dB
0.15
0.1
0.05
0
−0.05
−0.1
0
2000
4000
6000 8000 10000 12000
Frequency − Hz
14000
16000
De-Emphasis Filter Frequency Response at 44.1 ksps
Digital De-Emphasis Frequency Response For Fs = 44.1 kHz
0
−1
−2
Gain − dB
−3
−4
−5
−6
−7
−8
−9
−10
0
66
0.5
1
1.5
Frequency − Hz
2
x 104
www.ti.com
SLAS378− NOVEMBER 2003
De-Emphasis Error at 44.1 ksps
De-Emphasis Error With Respect to Ideal Frequency Response For Fs = 44.1 kHz
0.3
0.25
0.2
Gain − dB
0.15
0.1
0.05
0
−0.05
−0.1
0
0.5
1
1.5
Frequency − Hz
2
2.5
x 104
De-Emphasis Frequency Response at 48 ksps
Digital De-Emphasis Frequency Response at Fs = 48 kHz
0
−1
−2
Gain − dB
−3
−4
−5
−6
−7
−8
−9
−10
0
0.5
1
1.5
Frequency − Hz
2
2.5
x 104
67
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SLAS378− NOVEMBER 2003
De-Emphasis Error at 48 ksps
De-Emphasis Error With Respect to Ideal Frequency Response For Fs = 48 kHz
0.3
0.25
0.2
Gain − dB
0.15
0.1
0.05
0
−0.05
−0.1
0
0.5
1
1.5
Frequency − Hz
2
2.5
x 104
PLL PROGRAMMING
The on-chip PLL in the TSC2100 can be used to generate sampling clocks from a wide range of MCLK’s available in a
system. The PLL works by generating oversampled clocks with respect to Fsref (44.1 kHz or 48 kHz). Frequency division
generates all other internal clocks. The table below gives a sample programming for PLL registers for some standard
MCLK’s when PLL is required. Whenever the MCLK is of the form of N*128*Fsref (N=2,3…), PLL is not required.
Fsref = 44.1 kHz
MCLK (MHz)
P
J
D
ACHIEVED FSREF
% ERROR
2.8224
1
32
0
44100.00
0.0000
5.6448
1
16
0
44100.00
0.0000
12
1
7
5264
44100.00
0.0000
13
1
6
9474
44099.71
0.0007
16
1
5
6448
44100.00
0.0000
19.2
1
4
7040
44100.00
0.0000
19.68
1
4
5893
44100.30
−0.0007
48
4
7
5264
44100.00
0.0000
Fsref = 48 kHz
68
MCLK (MHz)
P
J
D
ACHIEVED FSREF
% ERROR
2.048
1
48
0
48000.00
0.0000
3.072
1
32
0
48000.00
0.0000
4.096
1
24
0
48000.00
0.0000
6.144
1
16
0
48000.00
0.0000
8.192
1
12
0
48000.00
0.0000
12
1
8
1920
48000.00
0.0000
13
1
7
5618
47999.71
0.0006
16
1
6
1440
48000.00
0.0000
19.2
1
5
1200
48000.00
0.0000
19.68
1
4
9951
47999.79
0.0004
48
4
8
1920
48000.00
0.0000
MECHANICAL DATA
MTSS002C – JANUARY 1995 – REVISED DECEMBER 1998
DA (R-PDSO-G**)
PLASTIC SMALL-OUTLINE
38 PINS SHOWN
0,30
0,19
0,65
38
0,13 M
20
6,20
NOM
8,40
7,80
0,15 NOM
Gage Plane
1
19
0,25
A
0°– 8°
0,75
0,50
Seating Plane
0,15
0,05
1,20 MAX
PINS **
0,10
30
32
38
A MAX
11,10
11,10
12,60
A MIN
10,90
10,90
12,40
DIM
4040066 / D 11/98
NOTES: A.
B.
C.
D.
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Body dimensions do not include mold flash or protrusion.
Falls within JEDEC MO-153
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1
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