Philips TDA1310A, TDA1310AT Datasheet

INTEGRATED CIRCUITS
DATA SH EET
TDA1310A
Preliminary specification Supersedes data of TDA1310; TDA1310T July 1993 File under Integrated Circuits, IC01
Philips Semiconductors
May 1994
Philips Semiconductors Preliminary specification
Stereo Continuous Calibration DAC (CC-DAC)

FEATURES

Space saving package DIL8 or SO8
Low power consumption
Wide dynamic range (16-bit resolution)
Continuous Calibration (CC) concept
Easy application:
– Single 3 to 5 V supply rail – Output current and bias current are proportional to
the supply voltage
Fast settling time permits 2×, 4× and 8× oversampling (serial input) or double speed operation at 4× oversampling
Internal bias current ensures maximum dynamic range
Wide operating temperature range (-40 t +85 °C)
Compatible with most current Japanese input formats:
– Time multiplexed – Two’s complement – TTL
No zero-crossing distortion.
TDA1310A

GENERAL DESCRIPTION

The TDA1310A is a device of a new generation of Digital-to-Analog Converters (DACs) which embodies the innovative technique of Continuous Calibration. The largest bit-currents are repeatedly generated by one single current reference source. This duplication is based upon an internal charge storage principle having an accuracy insensitive to ageing, temperature and process variations.
The TDA1310A is fabricated in a 1.0 µm CMOS process and features an extremely low power dissipation, small package size and easy application. Furthermore, the accuracy of the intrinsic high coarse-current combined with the implemented symmetrical offset decoding method precludes zero-crossing distortion and ensures high quality audio reproduction. Therefore, the CC-DAC is eminently suitable for use in (portable) digital audio equipment.

ORDERING INFORMATION

TYPE NUMBER
PINS PIN POSITION MATERIAL CODE
TDA1310A 8 DIL8 plastic SOT97DE TDA1310AT 8 SO8 plastic SOT96AG
PACKAGE
May 1994 2
Philips Semiconductors Preliminary specification
Stereo Continuous Calibration DAC
TDA1310A
(CC-DAC)

QUICK REFERENCE DATA

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT
V
DD
I
DD
I
FS
(THD+N)/S total harmonic distortion
S/N signal-to-noise ratio at
t
CS
BR input bit rate at data input −− 18.4 Mbits/s f
clk
TC
FS
T
amb
P
tot
supply voltage 3 5.0 5.5 V supply current VDD= 5 V at code 0000H 3.0 4.0 mA full scale output current VDD= 5 V 0.9 1.0 1.1 mA
V
=3V 0.6 mA
DD
at 0 dB signal level −−65 61 dB
plus noise-to-signal ratio
0.05 0.08 %
at 60 dB signal level −−30 24 dB
36%
at 60 dB signal level; A-weighted
at 60 dB signal level;
−−33 dB
2.2 %
1.7 %
A-weighted; R3=R4=11kΩ; (see Fig.1); I
=2mA
FS
A-weighted at code 0000H 86 92 dB
bipolar zero
A-weighted; I
= 2 mA;
FS
95 dB
R3=R4=11kΩ; see Fig.1
current settling time to
0.2 −µs
±1 LSB
clock frequency at clock
−− 18.4 MHz
input BCK full scale temperature
−±400 × 106 coefficient at analog outputs (IOL; IOR)
operating ambient
40 +85 °C temperature
total power dissipation VDD= 5 V at code 0000H 15 20 mW
= 3 V at code 0000H 6.0 mW
V
DD
May 1994 3
May 1994 4

BLOCK DIAGRAM

(CC-DAC)
Philips Semiconductors Preliminary specification
Stereo Continuous Calibration DAC
Fig.1 Block diagram.
TDA1310A
Philips Semiconductors Preliminary specification
Stereo Continuous Calibration DAC (CC-DAC)

PINNING

SYMBOL PIN DESCRIPTION
BCK 1 bit clock input WS 2 word select input DATA 3 data input GND 4 ground V
DD
I
OL
I
ref
I
OR

FUNCTIONAL DESCRIPTION

The basic operation of the continuous calibration DAC is illustrated in Fig.3. The figure shows the calibration and operation cycle. During calibration of the MOS current source (Fig.3a) transistor M1 is connected as a diode by applying a reference current. The voltage Vgs on the intrinsic gate-source capacitance Cgs of M1 is then determined by the transistor characteristics. After calibration of the drain current to the reference value I the switch S1 is opened and S2 is switched to the other position (Fig.3b). The gate-to-source voltage Vgs of M1 is not changed because the charge on Cgs is preserved. Therefore, the drain current of M1 will still be equal to I and this exact duplicate of I terminal.
The 32 current sources and the spare current source of the TDA1310A are continuously calibrated (see Fig.1). The spare current source is included to allow continuous converter operation. The output of one calibrated source is connected to an 11-bit binary current divider consisting of 2048 transistors. A symmetrical offset decoding principle is incorporated and arranges the bit switching in such a way that the zero-crossing is performed only by switching the LSB currents.
5 supply voltage 6 left channel output 7 reference input 8 right channel output
is now available at the OUT
ref
ref
ref
TDA1310A
Fig.2 Pin configuration.
An internal bias current I output current IFS in order to achieve the maximum dynamic range at the outputs OP1 and OP2 in Fig.1.
The reference input current I current IFS which is a sink current and with gain G I
which is a source current
bias
,
The current I
is proportional to VDD so the IFS and the I
ref
will be proportional to VDD as well are constant.
The reference voltage V maximum dynamic range is achieved over the entire power supply voltage range.
The tolerance of the reference input current in Fig.1 depends on the tolerance of the resistors R3, R4
ref
(3)
.
and R
is added to the full scale
bias
controls with gain GFS, the
ref
(1)
.
(2)
because GFS and G
in Fig.1 is2⁄3VDD. In this way
ref
bias
the
bias bias
The TDA1310A (CC-DAC) accepts serial input data formats of 16-bit word length. Left and right data words are time multiplexed. The most significant bit (bit 1) must always be first. The input data format is shown in Figs 4 and 5.
With a HIGH level on the word select input (WS), data is placed in the left input register, with a LOW level on the WS input, data is placed in the right input register (see Fig.1). The data in the input registers are simultaneously latched in the output registers which control the bit switches.
May 1994 5
(1) IFS=GFSxI
(2)
(3)
V
------------­V
I
I
DD1
==
---------­I
DD2
refIref
and I
ref
bias=GbiasxIref
I
FS1 FS2
bias1
------------- ­I
bias2
V
=
------------------------------------------------------------------------------------------------­R3 R3 R4 R4 R
+++++
DD
ref
R
ref
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