MICROCHIP TC530COI

TC530/TC534
5V Precision Data Acquisition Subsystems
Package Types
Features
28-Pin SOIC
28-Pin PDIP
• Precision (up to 17-Bits) A/D Converter
• 3-Wire Serial Port
• Flexible: User Can Trade Off Conversion Speed For
Resolution
• Single Supply Operation
• -5V Output Pin
• 4 Input, Differential Analog MUX (TC534)
• Automatic Input Polarity and Overrange Detection
• Low Operating Current: 5mA Max
• Wide Analog Input Range: ±4.2V Max
• Cost Effective
VSS 1
28 CAP-
CINT 2
27 AGND
CAZ 3
26 CAP+
BUF 4
25 VDD
ACOM 5
CREF- 6
24 NC
VREF- 8
21 RESET
VREF+ 9
VIN- 10
20 EOC
23 OSC
TC530CPI
CREF+ 7 TC530COI 22 VCCD
18 DIN
DGND 12
17 DCLK
N/C 13
16 DOUT
15 OSCIN
OSCOUT 14
Applications
40-Pin PDIP
• Precision Analog Signal Processor
• Precision Sensor Interface
• High Accuracy DC Measurements
VSS 1
40 CAP-
CINT 2
CAZ 3
39 AGND
38 CAP+
37 VDD
BUF 4
36 N/C
ACOM 5
CREF- 6
CREF+ 7
Device Selection Table
VREF-
35 N/C
34 OSC
33 N/C
8
VREF+ 9
Part Number
19 R/W
VIN+ 11
Package
Temperature
Range
32 VCCD
TC534CPL
CH4- 10
31 N/C
CH3- 11
30 RESET
CH2- 12
29 N/C
TC530COI
28-Pin SOIC
0°C to +70°C
CH1- 13
28 N/C
TC530CPJ
28-Pin PDIP (Narrow)
0°C to +70°C
CH4+ 14
27 EOC
26 R/W
TC534CKW
44-Pin PQFP
0°C to +70°C
CH3+ 15
CH2+ 16
TC534CPL
40-Pin PDIP
0°C to +70°C
CH1+ 17
24 DCLK
DGND 18
23 DOUT
25 DIN
A1 19
22 OSCIN
A0 20
21 OSCOUT
NC
VDD
AGND
CAP+
CAP-
NC
VSS
CINT
CAZ
BUF
NC
44-Pin PQFP
44 43 42 41 40 39 38 37 36 35 34
NC
1
33 NC
ACOM
2
32 OSC
CREF-
3
31 NC
CREF+
4
30 VCDD
VREF-
5
VREF+
6
CH4-
7
27 NC
CH3-
8
26 NC
CH2-
9
25 NC
29
TC534CKW
NC
28 RESET
CH1- 10
24 EOC
CH4+ 11
23 R/W
 2002 Microchip Technology Inc.
DIN
DCLK
DOUT
OSCIN
OSCOUT
A0
A1
DGND
CH1+
CH2+
CH3+
12 13 14 15 16 17 18 19 20 21 22
DS21433B-page 1
TC530/TC534
new data is available. The converted data (plus Overrange and polarity bits) is held in the output shift register until read by the processor or until the next
conversion is completed, allowing the user to access
data at any time.
General Description
The TC530/TC534 are serial analog data acquisition
subsystems ideal for high precision measurements (up
to 17-bits plus sign). The TC530 consists of a dual
slope integrating A/D converter, negative power supply generator and 3 wire serial interface port. The
TC534 is identical to the TC530, but adds a four channel differential input multiplexer. Key A/D converter
operating parameters (Auto Zero and Integration time)
are programmable, allowing the user to trade
conversion time for resolution.
The TC530/TC534 timebase can be derived from an
external crystal of 2MHz (max) or from an external frequency source. The TC530/TC534 requires a single 5V
power supply and features a -5V, 10mA output which
can be used to supply negative bias to other
components in the system.
Data conversion is initiated when the RESET input is
brought low. After conversion, data is loaded into the
output shift register and EOC is asserted, indicating
Typical Application
VDD
CINT
+5V
RINT
VDD
(TC530 Only)
VINVIN+
.01µF
DIF.
MUX
CH3+
CH3-
(TC534
Only)
TC530
TC534
VREF- ACOM
0.01µF
CMPTR A
B
EOC
VDD
R/W
Serial Port
DC-TO-DC
Converter
Oscillator
(÷ 4)
VSS
OSC
CAP+
CAP–
Optional
Power-On
Reset Cap
RESET
State
Machine
CH4+
CH4-
A0 A1
VREF+
INT CREF+ CREF-
Dual Slope A/D Converter
IN+
IN-
CH2+
CH2-
DS21433B-page 2
100k
CREF
VDD
BUF CAZ
CH1+
CH1-
TC534
(Only)
CAZ
MCP1525
OSCIN
DIN
DOUT
DCLK
OSCOUT
Negative
Supply Output
 2002 Microchip Technology Inc.
TC530/TC534
1.0
ELECTRICAL
CHARACTERISTICS
*Stresses above 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 above those indicated in the
operation sections of the specifications is not implied. Exposure to Absolute Maximum Rating conditions for extended
periods may affect device reliability.
Absolute Maximum Ratings*
Supply Voltage ...................................................... +6V
Analog Input Voltage (VIN+ or VIN-).............VDD to VSS
Logic Input Voltage......... (V DD + 0.3V) to (GND - 0.3V)
Ambient Operating Temperature Range:
PDIP Package (C)................. 0°C to +70°C
SOIC Package (C) ................ 0°C to +70°C
PQFP Package (C) ............... 0°C to +70°C
Storage Temperature Range .............. -65°C to +150°C
TC530/TC530A/TC534 ELECTRICAL SPECIFICATIONS
Electrical Characteristics: VDD = VCCD, C AZ = CREF = 0.47µF, unless otherwise specified.
Symbol
TA = +25°C
Parameter
Min
Typ
TA = 0°C to +70°C
Max
Min
Typ
Unit
Test Conditions
Max
V DD
Analog Power Supply Voltage
4.5
5.0
5.5
4.5
—
5.5
V
VCCD
Digital Power Supply Voltage
4.5
5.0
5.5
4.5
—
5.5
V
PD
TC530/TC534 Total Power
Dissipation
—
—
25
—
—
—
mΩ
IS
Supply Current (VS + PIN )
—
1.8
2.5
—
—
3.0
mA
ICCD
Supply Current (VCCD PIN)
—
—
1.5
—
—
1.7
mA
FOSC = 1MHz
Note 1
VDD = VCCD = 5V
Analog
Resolution
—
—
±17
—
—
±17
Bits
ZSE
R
Zero Scale Error with Auto
Zero Phase
—
—
0.5
—
0.005
0.012
% F.S.
ENL
End Point Linearity
—
0.015
0.030
—
0.015
0.045
% F.S. Note 1 and
Note 2
NL
Max. Deviation from Best
Straight Line Fit
—
0.008
0.015
—
—
—
% F.S. Note 1 and
Note 2
ZSTC
Zero Scale Temperature
Coefficient
—
—
—
—
1
2
µV/°C
SYE
Rollover Error
—
.012
—
—
.03
—
% F.S. Note 3
FSTC
Full Scale Temperature
Coefficient
—
—
—
—
10
—
ppm/
°C
—
6
—
—
—
—
pA
VCMR
Common-Mode Voltage
Range
VSS + 1.5
—
VDD - 1.5
VSS + 1.5
—
VDD - 1.5
V
VINT
Integrator Output Swing
VSS + 0.9
—
VDD - 0.9
VSS + 0.9
—
VDD - 0.9
V
VIN
Analog Input Signal Range
VSS + 1.5
—
VDD -1.5
VSS + 1.5
—
VDD - 1.5
V
VREF
Voltage Reference Range
VSS + 1
—
VDD - 1
VDD + 1
—
VDD - 1
V
—
2.0
—
3.0
—
µsec
IIN
TD
Note 1:
2:
3:
4:
Input Current
Zero Crossing
Comparator Delay
—
Ext. VREF
T.C. = 0ppm/°C
VIN = 0V
Integrate time ≥ 66msec, Auto Zero time ≥ 66msec, VINT (pk) = 4V.
End point linearity at ±1/4, ±1/2 ±3/4, F.S. after full scale adjustment.
Rollover error is related to capacitor used for CINT. See Table 5-2, Recommended Capacitor for C INT.
TC534 Only.
 2002 Microchip Technology Inc.
DS21433B-page 3
TC530/TC534
TC530/TC530A/TC534 ELECTRICAL SPECIFICATIONS (CONTINUED)
Electrical Characteristics: VDD = VCCD, C AZ = CREF = 0.47µF, unless otherwise specified.
Symbol
TA = +25°C
Parameter
Min
Typ
TA = 0°C to +70°C
Max
Min
Typ
Unit
Test Conditions
Max
Serial Port Interface
VIH
Input Logic HIGH Level
2.5
—
—
2.5
—
—
VIL
Input Logic LOW Level
—
—
0.8
—
—
0.8
V
IIN
Input Current
(DI, DO, DCLK)
—
—
10
—
—
—
µA
Logic LOW Output Voltage
(EOC)
—
0.2
0.3
—
—
0.35
V
IOUT = 250µA
Rise and Fall Times
(EOC, DI, DO)
—
—
250
—
250
nsec
CL = 10pF
VOL
T R, T F
V
FXTL
Crystal Frequency
—
—
2.0
—
—
2.0
MHz
FEXT
External Frequency on OSCIN
—
—
4.0
—
—
4.0
MHz
—
µsec
TRS
Read Setup Time
1
—
—
—
1
TRD
Read Delay Time
250
—
—
—
250
nsec
TDRS
DCLK to D OUT Delay
450
—
—
—
450
nsec
TPWL
DCLK LOW Pulse Width
150
—
—
—
150
nsec
TPWH
DCLK HIGH Pulse Width
150
—
—
—
150
nsec
TDR
Data Ready Delay
200
—
—
—
200
nsec
ROUT
Output Resistance
—
65
85
—
—
100
Ω
IOUT = 10mA
FCLK
Oscillator Frequency
—
100
—
—
—
—
kHz
COSC = 0
IOUT
VSS Output Current
—
—
10
—
—
10
mA
-2.5
—
2.5
-2.5
—
2.5
V
—
6
10
—
—
—
kΩ
Multiplexer
VIMMAX Maximum Input Voltage
RDSON
Note 1:
2:
3:
4:
Drain/Source ON Resistance
Integrate time ≥ 66msec, Auto Zero time ≥ 66msec, VINT (pk) = 4V.
End point linearity at ±1/4, ±1/2 ±3/4, F.S. after full scale adjustment.
Rollover error is related to capacitor used for CINT. See Table 5-2, Recommended Capacitor for C INT.
TC534 Only.
DS21433B-page 4
 2002 Microchip Technology Inc.
TC530/TC534
2.0
PIN DESCRIPTIONS
The descriptions of the pins are listed in Table 2-1
TABLE 2-1:
PIN FUNCTION TABLE
Pin Number Pin Number
(TC530)
(TC530)
28-Pin PDIP 28-Pin SOIC
Pin Number
(TC534)
40-Pin PDIP
Pin Number
(TC534)
Symbol
44-Pin
PQFP
Description
1
1
1
40
VSS
Analog output. Negative power supply converter output and
reservoir capacitor connection. This output can be used to
provide negative bias to other devices in the system.
2
2
2
41
CINT
Analog output. Integrator capacitor connection and
integrator output.
3
3
3
42
CAZ
Analog input. Auto Zero capacitor connection.
4
4
4
43
BUF
Analog output. Integrator capacitor connection and voltage
buffer output.
5
5
5
2
ACOM
6
6
6
3
CREF-
Analog Input. Reference cap negative connection.
7
7
7
4
CREF+
Analog Input. Reference cap positive connection.
8
8
8
5
VREF-
Analog Input. External voltage reference negative connection.
9
9
9
6
VREF+
Analog Input. External voltage reference positive connection.
Not Used
Not Used
10
7
CH4-
Analog Input. Multiplexer channel 4 negative differential
Not Used
Not Used
11
8
CH3-
Analog Input. Multiplexer channel 3 negative differential
Not Used
Not Used
12
9
CH2-
Analog Input. Multiplexer channel 2 negative differential
Analog input. This pin is ground for all of the analog
switches in the A/D converter. It is grounded for most
applications. ACOM and the input common pin (VIN - or
CHX-) should be within the common mode range, CMR.
Not Used
Not Used
13
10
CH1-
Analog Input. Multiplexer channel 1 negative differential
Not Used
Not Used
14
11
CH4+
Analog Input. Multiplexer channel 4 positive differential
Not Used
Not Used
15
12
CH3+
Analog Input. Multiplexer channel 3 positive differential
Not Used
Not Used
16
13
CH2+
Analog Input. Multiplexer channel 2 positive differential
Not Used
Not Used
17
14
CH1+
Analog Input. Multiplexer channel 1 positive differential
10
10
Not Used
Not Used
VN-
Analog Input. Negative differential analog voltage input.
11
11
Not Used
Not Used
VIN +
Analog Input. Positive differential analog voltage input.
12
12
18
15
DGND
Analog Input. Ground connection for serial port circuit.
Not Used
Not Used
19
16
A1
Logic Level Input. Multiplexer address MSB.
Not Used
Not Used
20
17
A0
Logic Level Input. Multiplexer address LSB.
14
14
21
18
15
15
22
19
 2002 Microchip Technology Inc.
OSCOUT Analog Input. Timebase for state machine. This pin connects to one side of an AT-cut crystal having an effective
series resistance of 100Ω (typ) and a parallel capacitance of
20pF. If an external frequency source is used to clock the
TC530/TC534 this pin must be left floating.
OSCIN
Analog Input. This pin connects to the other side of the crystal described in OSCOUT above. The TC530/TC534 may
also be clocked from an external frequency source connected to this pin. The external frequency source must be a
pulse wave form with a minimum 30% duty cycle and rise
and fall times 15nsec (Max). If an external frequency source
is used, OSCOUT must be left floating. A maximum operating frequency of 2MHz (crystal) or 4MHz (external clock
source) is permitted.
DS21433B-page 5
TC530/TC534
TABLE 2-1:
PIN FUNCTION TABLE (CONTINUED)
Pin Number Pin Number
(TC530)
(TC530)
28-Pin PDIP 28-Pin SOIC
Pin Number
(TC534)
40-Pin PDIP
Pin Number
(TC534)
Symbol
44-Pin
PQFP
Description
16
16
23
20
DOUT
Logic Level Output. Serial port data output pin. This pin is
enabled only when R/W is high.
17
17
24
21
DCLK
Logic Input, Positive and Negative Edge Triggered. Serial
port clock. When R/W is high, serial data is clocked out of
the TC530/TC534A (on DOUT ) at each high-to-low transition
of DCLK. A/D initialization data (LOAD VALUE) is clocked
into the TC530/TC534 (on DIN ) at each low-to-high transition of DCLK. A maximum serial port DCLK frequency of
3MHz is permitted.
18
18
25
22
DIN
Logic Level Input. Serial port input pin. The A/D converter
integration time (TINT) and Auto Zero time (TAZ) values are
determined by the LOAD VALUE byte clocked into this pin.
This initialization must take place at power up, and can be
rewritten (or modified and rewritten) at any time. The LOAD
VALUE is clocked into DIN MSB first.
19
19
26
23
R/W
Logic Level Input. This pin must be brought low to perform a
write to the serial port (e.g. initialize the A/D converter). The
DOUT pin of the serial port is enabled only when this pin is
high.
20
20
27
24
EOC
Open Drain Output. End-of-Conversion (EOC) is asserted
any time the TC530/TC534 is in the AZ phase of conversion. This occurs when either the TC530/TC534 initiates a
normal AZ phase or when RESET is pulled high. EOC is
returned high when the TC530/TC534 exits AZ. Since EOC
is driven low immediately following completion of a conversion cycle, it can be used as a DATA READY processor
interrupt.
21
21
30
28
RESET
Logic Level Input. It is necessary to force the TC530/TC534
into the Auto Zero phase when power is initially applied.
This is accomplished by momentarily taking RESET high.
Using an I/O port line from the microprocessor or by applying an external system reset signal or by connecting a
0.01µF capacitor from the RESET input to VDD. Conversions are performed continuously as long as RESET is low
and conversion is halted when RESET is high. RESET may
therefore be used in a complex system to momentarily suspend conversion (for example, while the address lines of an
input multiplexer are changing state). In this case, RESET
should be pulled high only when the EOC is LOW to avoid
excessively long integrator discharge times which could
result in erroneous conversion. (See Applications Section).
22
22
32
30
VCCD
Analog Input. Power supply connection for digital logic and
serial port. Proper power-up sequencing is critical, see the
Applications section.
23
23
34
32
OSC
Input. The negative power supply converter normally runs at
a frequency of 100kHz. This frequency can be slowed down
to reduce quiescent current by connecting an external
capacitor between this pin and V+DD.
See Section 6.0, Typical Characteristics.
25
25
37
35
VDD
Analog Input. Power supply connection for the A/D analog
section and DC-DC converter. Proper power-up sequencing
is critical, (See the Applications section).
DS21433B-page 6
 2002 Microchip Technology Inc.
TC530/TC534
TABLE 2-1:
PIN FUNCTION TABLE (CONTINUED)
Pin Number Pin Number
(TC530)
(TC530)
28-Pin PDIP 28-Pin SOIC
Pin Number
(TC534)
40-Pin PDIP
Pin Number
(TC534)
Symbol
44-Pin
PQFP
Description
26
26
38
36
CAP+
Analog Input. Storage capacitor positive connection for the
DC/DC converter.
27
27
39
37
AGND
Analog Input. Ground connection for DC/DC converter.
28
28
40
38
CAP-
Analog Input. Storage capacitor negative connection for the
DC/DC converter.
13, 24
13, 24
28, 29, 31,
33, 35, 36
1, 25, 26, 27,
29, 31, 33,
34, 39, 44
NC
 2002 Microchip Technology Inc.
No connect. Do not connect any signal to these pins.
DS21433B-page 7
TC530/TC534
3.0
DETAILED DESCRIPTION
3.1
Dual Slope Integrating Converter
The TC530/TC534 dual slope converter operates by
integrating the input signal for a fixed time period, then
applying an opposite polarity reference voltage while
timing the period (counting clocks pulses) for the integrator output to cross 0V (deintegrating). The resulting
count is read as conversion data.
A simple mathematical expression that describes dual
slope conversion is:
In addition to the two phases required for dual slope
measurement (Integrate and De-integrate), the TC530/
TC534 performs two additional adjustments to
minimize measurement error due to system offset voltages. The resulting four internal operations (conversion phases) performed each measurement cycle are:
Auto Zero (AZ), Integrator Output Zero (IZ), Input Integrate (INT) and Reference De-integrate (DINT). The
AZ and IZ phases compensate for system offset errors
and the INT and DINT phases perform the actual A/D
conversion.
FIGURE 3-1:
EQUATION 3-1:
EQUATION 3-2:
TINT
TDEINT
1
1
∫
∫
VREF
VIN(T)DT =
R INTCINT 0
RINTCINT 0
from which:
EQUATION 3-3:
(V IN)
[
(T INT)
(RINT)(CINT)
]
= (VREF)
[
(TDEINT)
(RINT)(CINT)
]
Normal Mode Rejection (dB)
Integrate Voltage = De-integrate Voltage
And therefore:
3.2
EQUATION 3-4:
[ ]
VIN = VREF
TDEINT
T INT
where:
VREF = Reference Voltage
TINT = Integrate Time
INTEGRATING
CONVERTER NORMAL
MODE REJECTION
30
T = Measurement
Period
20
10
0
0.1/T
1/T
Input Frequency
10/T
Auto Zero Phase (AZ)
This phase compensates for errors due to buffer, integrator and comparator offset voltages. During this
phase, an internal feedback loop forces a compensating error voltage on auto zero capacitor (CAZ). The
duration of the AZ phase is programmable via the serial
port (see Section 4.1.1, AZ and INT Phase Duration).
TDEINT = Reference Voltage De-integrate Time
Inspection of Equation 3-4 shows dual slope converter
accuracy is unrelated to integrating resistor and capacitor values, as long as they are stable throughout the
measurement cycle. This measurement technique is
inherently ratiometric (i.e., the ratio between the TINT
and TDEINT times is equal to the ratio between VIN and
VREF).
Another inherent benefit is noise immunity. Input noise
spikes are integrated, or averaged to zero, during the
integration period. The integrating converter has a noise
immunity with an attenuation rate of at least -20dB per
decade. Interference signals with frequencies at integral
multiples of the integration period are, for the most part,
completely removed. For this reason, the integration
period of the converter is often established to reject 50/
60Hz line noise. The ability to reject such noise is shown
by the plot of Figure 3-1.
DS21433B-page 8
 2002 Microchip Technology Inc.
TC530/TC534
FIGURE 3-2:
SERIAL PORT TIMING
Read Timing
Write Timing
Write Default Timing
TRS
R/W
R/W
TRD
R/W
TLS
EOC
TLDL
DIN
DIN
TDLS
TPWL
DOUT
TDRS
TPWL
TLDS
DCLK
DCLK
Read Format
R/W
EOC
DOUT
EOC OVR SGN MSB
LSB
DCLK
Write Format
R/W
DOUT
MSB
LSB
DCLK
For Polled vs Interrupt Operation and Write Value Modified Cycle Use TC520A Data Sheet (DS21431).
FIGURE 3-3:
A/D CONVERTER TIMING
Conversion
Phase
Data to Serial
Port Transmit
Register
AZ
INT
Updated Data
Ready
DINT
IZ
AZ
Updated Data
Ready
TDR
EOC
3.3
Input Integrate Phase (INT)
In this phase, a current directly proportional to differential input voltage is sourced into integrating capacitor
CINT. The amount of voltage stored on CINT at the end
of the INT phase is directly proportional to the applied
differential input voltage. Input signal polarity (sign bit)
is determined at the end of this phase. Converter
resolution and speed is a function of the duration of the
INT phase, which is programmable by the user via the
serial port (see Section 4.1.1, AZ and INT Phase Duration). The shorter the integration time, the faster the
 2002 Microchip Technology Inc.
speed of conversion (but the lower the resolution).
Conversely, the longer the integration time, the greater
the resolution (but at slower the speed of conversion).
DS21433B-page 9
TC530/TC534
3.4
Reference De-integrate Phase
(DINT)
This phase consists of measuring the time for the integrator output to return (at a rate determined by the
external reference voltage) from its initial voltage to 0V.
The resulting timer data is stored in the output shift register as converted analog data.
3.5
Integrator Output Zero Phase (IZ)
This phase ensures the integrator output is at zero volts
when the AZ phase is entered so that only true system
offset voltages will be compensated for.
All internal converter timing is derived from the frequency source at OSC IN and OSCOUT. This frequency
source must be either an externally provided clock
signal or an external crystal. If an external clock is
used, it must be connected to the OSCIN pin and the
OSC OUT pin must remain floating. If a crystal is used, it
must be connected between OSCIN and OSCOUT and
be physically located as close to the OSCIN and
OSC OUT pins as possible. In either case, the incoming
clock frequency is divided by four, with the resulting
clock serving as the internal TC530/TC534 timebase.
4.0
TYPICAL APPLICATIONS
4.1
Programming the TC530/TC534
4.1.1
AZ AND INT PHASE DURATION
These two phases have equal duration determined by
the crystal (or external) frequency and the timer initialization byte (LOAD VALUE). Timing is selected as
follows:
1.
Select Integration Time
Integration time must be picked as a multiple of the
period of the line frequency. For example, TINT
times of 33msec, 66msec and 132msec maximize
60Hz line rejection.
2.
3.
EQUATION 4-2:
[LOAD VALUE]10 =
EQUATION 4-1:
2(R)/TINT
where:
R
= Desired Converter Resolution (in counts)
FIN = Input Frequency (in MHz)
INT = Integration Time (in seconds)
256 - (TINT)(FIN)
1024
FIN can be adjusted to a standard value during this
step. The resulting base, -10 LOAD VALUE, must be
converted to a hexadecimal number and then loaded
into the serial port prior to initiating A/D conversion.
4.2
DINT and IZ Phase Timing
The duration of the DINT phase is a function of the
amount of voltage stored on the integrator capacitor
during INT and the value of VREF. The DINT phase is initiated immediately following INT and terminated when
an integrator output zero crossing is detected. In general, the maximum number of counts chosen for DINT is
twice that of INT (with VREF chosen at VIN(MAX)/2).
4.3
System RESET
The TC530/TC534 must be forced into the AZ state
when power is first applied. A .01µF capacitor connected from RESET to VDD (or external system reset
logic signal) can be used to momentarily drive RESET
high for a minimum of 100msec.
4.4
Design Example
Figure 4-1 shows a typical TC534 interrupt-driven
application. Timing and component values are calculated from equations and recommendations made in
Section 3.1 and Section 4.1 of this document. The
EOC connection to the processor INT input is for interrupt-driven applications only. (In polled systems, the
EOC output is available on DOUT).
Given:
Required resolution:16-bits (65,536 counts.)
Maximum: VIN ±2V
Estimate Crystal Frequency
Crystal frequencies as high as 2MHz are allowed.
Crystal frequency is estimated using:
Calculate LOAD VALUE
Power supply voltage: +5V
60hz system
1.
2.
Pick Integration time (TINT): 66msec
Estimate crystal frequency.
EXAMPLE 4-1:
FIN = 2R/TINT = 2 x 65536/66 x 10-3 = 1.98MHz
(use 2MHz)
3.
Calculate LOAD VALUE
EXAMPLE 4-2:
LOAD VALUE = 256 – (T INT)(FIN)/1024 = [128]10
[128] 10 = 80 hex
DS21433B-page 10
 2002 Microchip Technology Inc.
TC530/TC534
4.
Calculate RINT
4.6
EXAMPLE 4-3:
RINT = VINMAX/20 = 2/20 = 100kΩ
5.
1.
Calculate CINT for maximum (4V) integrator output swing:
EXAMPLE 4-4:
CINT = (TINT)(20 x 10–6 )/ (VS – 0.9)
= (.066)(20 x 10–6)/(4.1)
2.
= .32µF (use closest value: 0.33µF)
Note:
6.
Microchip recommended capacitor:
Evox-Rifa p/n: SMR5 334K50J03L
Choose CREF and CAZ based on conversion
rate:
EXAMPLE 4-5:
Conversions/sec
= 1/(TAZ + TINT + 2TINT + 2msec)
3.
= 1/(66msec + 66msec + 132msec + 2msec)
= 3.7 conversions/sec
from which CAZ = C REF = 0.22µF (Table 5-1)
4.
Note:
7.
Microchip recommended capacitor:
Evox-Rifa p/n: SMR5 224K50J02L4
Calculate VREF.
5.
EXAMPLE 4-6:
VREF =
(V S – 0.9) (C INT) (R INT)
2(TINT)
= (4.1) (0.33 x 1 –6) (105) / 2(.066)
6.
= 1.025V
4.5
Power Supply Sequencing
Improper sequencing of the power supply inputs (VDD
vs. VCCD) can potentially cause an improper power-up
sequence to occur. See Section 4.6, Circuit Design/
Layout Considerations. Failing to insure a proper
power-up sequence can cause spurious operation.
 2002 Microchip Technology Inc.
7.
Circuit Design/Layout
Considerations
Separate ground return paths should be used
for the analog and digital circuitry. Use of ground
planes and trace fill on analog circuit sections is
highly recommended EXCEPT for in and around
the integrator section and CREF, CAZ (C INT,
CREF, C AZ, RINT). Stray capacitance between
these nodes and ground appears in parallel with
the components themselves and can affect
measurement accuracy.
Improper sequencing of the power supply inputs
(VDD vs. VCCD) can potentially cause an
improper power-up sequence to occur in the
internal state machines. It is recommended that
the digital supply, VCCD, be powered up first.
One method of insuring the correct power-up
sequence is to delay the analog supply using a
series resistor and a capacitor. See Figure 4-1,
TC530/TC534 Typical Application.
Decoupling capacitors, preferably a higher
value electrolytic or tantulum in parallel with a
small ceramic or tantalum, should be used liberally. This includes bypassing the supply connections of all active components and the voltage
reference.
Critical components should be chosen for stability and low noise. The use of a metal-film
resistor for RINT and Polypropylene or
Polyphenelyne Sulfide (PPS) capacitors for
CINT, CAZ and CREF is highly recommended.
The inputs and integrator section are very high
impedance nodes. Leakage to or from these critical nodes can contribute measurement error. A
guard-ring should be used to protect the integrator section from stray leakage.
Circuit assemblies should be exceptionally
clean to prevent the presence of contamination
from assembly, handling or the cleaning itself.
Minute conductive trace contaminates, easily
ignored in most applications, can adversely
affect the performance of high impedance circuits. The input and integrator sections should
be made as compact and close to the TC53X as
possible.
Digital and other dynamic signal conductors
should be kept as far from the TC53X’s analog
section as possible. The microcontroller or other
host logic should be kept quiet during a measurement cycle. Background activities such as
keypad scanning, display refreshing and power
switching can introduce noise.
DS21433B-page 11
TC530/TC534
TC530/TC534 TYPICAL APPLICATION
FIGURE 4-1:
+5V
+5V
C1
.01µF
VDD
.01µF
IN1+
RESET
IN1-
VCCD
10µF
100Ω
VDD
IN2+
VCCD
.01µF
I/O
IN3-
DOUT
I/O
IN4+
DIN
I/O
IN4-
DCLK
I/O
1µF
CAZ
0.22µF
CINT
CAZ
BUF
RINT
100k
CREF
0.22µF
MUX
Channel
Control
INT
R/W
IN3+
CIN
0.33µF
(Optional)
EOC
IN2Analog
Inputs
TC534
OSCIN
X1: 2MHz
OSCOUT
–5V
VSS
1µF
DGND
CREF+
CREFA0
A1
CAP+
1µF
Processor
+5V
R1
100k
R2
100k
VREF+
(1.03V)
VREFACOM
CAP-
DS21433B-page 12
 2002 Microchip Technology Inc.
TC530/TC534
5.0
SELECTING COMPONENT
VALUES FOR THE
TC530/TC534
Calculate Integrating Resistor (RINT)
1.
The desired full scale input voltage and amplifier
output current capability determine the value of
R INT. The buffer and integrator amplifiers each
have a full scale current of 20µA. The value of RINT
is therefore directly calculated as follows:
It is critical that the integrating capacitor have a very
low dielectric absorption. PPS capacitors are an example of one such dielectric. Table 5-2 summarizes
various capacitors suitable for CINT.
TABLE 5-2:
Value (µF)
Suggested Part Number*
EQUATION 5-1:
RINT =
VINMAX
mΩ
20
where:
Note:
5.2
VIN(MAX) = Maximum Input Voltage (full count voltage)
R INT = Integrating Resistor (in mΩ)
RECOMMENDED CAPACITOR
FOR CINT
0.1
SMR5 104K50J0IL
0.22
SMR5 224K50J2L
0.33
SMR5 334K50J03L4
0.47
SMR5 474K50J04L
*Manufactured by Evox-Rifa, Inc.
Calculate VREF
The reference de-integration voltage is calculated
using the following equaton:
For loop stability, RINT should be ≥ 50kΩ.
2.
Select Reference (CREF) and Auto Zero (CAZ)
Capacitors
C REF and CAZ must be low leakage capacitors
(such as polypropylene). The slower the conversion rate, the larger the value CREF must be. Recommended capacitors for CREF and CAZ are
shown in Table 5-1. Larger values for CAZ and
C REF may also be used to limit rollover errors.
TABLE 5-1:
C REF AND CAZ SELECTION
Conversion
Per Second
Typical Value of
C REF, C AZ (µF)
Suggested* Part
Number
>7
0.1
SMR5 104K50J0IL
2 to 7
0.22
SMR5 224K50J2L
2 or less
0.47
SMR5 474K50J04L
Note:
5.1
*Manufactured by Evox-Rifa, Inc.
Calculate Integrating Capacitor
(CINT)
The integrating capacitor must be selected to maximize
integrator output voltage swing. The integrator output
voltage swing is defined as the absolute value of VDD
(or VSS) less 0.9V (i.e.,IVDD – 0.9VI or IVSS +0.9VI).
Using the 20µA buffer maximum output current, the
value of the integrating capacitor is calculated using the
following equation.
VREF =
5.3
(VS – 0.9) (CINT) (RINT)
2(RINT)
V
Serial Port
Communication with the TC530/TC534 is accomplished over a 3 wire serial port. Data is clocked into
DIN on the rising edge of DCLK and clocked out of DOUT
on the falling edge of DCLK. R/W must be HIGH to read
converted data from the serial port and LOW to write
the LOAD VALUE to the TC530/TC534.
5.4
Data Read Cycle
Data is shifted out of the serial port in the following
order: End of Conversion (EOC), Overrange (OVR),
Polarity (POL), conversion data (MSB first). When R/W
is high, the state of the EOC bit can be polled by simply
reading the state of DOUT. This allows the processor to
determine if new data is available without connecting
an additional wire to the EOC output pin (this is especially useful in a polled environment). See Figure 5-1.
FIGURE 5-1:
SERIAL PORT DATA
READ CYCLE
R/W
DCLK
EQUATION 5-2:
(TINT) (20 x 10
CINT =
(V S - 0.9)
EQUATION 5-3:
-6)
µF
DOUT
EOC OVR POL MSB
LSB
where: TINT = Integration Period
VS = IVDD I
CINT = Integrated Capacitor Value (µF).
 2002 Microchip Technology Inc.
DS21433B-page 13
TC530/TC534
5.5
Load Value Write Cycle
5.6
Following the power-up reset pulse, the LOAD VALUE
(which sets the duration of AZ and INT) must next be
transmitted to the serial port. To accomplish this, the
processor monitors the state of EOC (which is available
as a hardware output or at DOUT). R/W is taken low to
initiate the write cycle only when EOC is low (during the
AZ phase). (Failure to observe EOC low may cause an
offset voltage to be developed across CINT, resulting in
erroneous readings). The 8-bit LOAD VALUE data on
DIN is clocked in by DCLK. The processor then terminates the write cycle by taking R/W high. (Data is
transferred from the serial input shift register to the time
base counter on the rising edge of R/W and data
conversion is initiated). See Figure 5-2.
FIGURE 5-2:
Timing
Status
A 4-input, differential multiplexer is included in the
TC534. The states of channel address lines A0 and A1
determine which differential VIN pair is routed to the
converter input. A0 is the least significant address bit
(i.e., channel 1 is selected when A0 = 0 and A1 = 0).
The multiplexer is designed to be operated in a differential mode. For single-ended inputs, the CHx- input for
the channel under selection must be connected to the
ground reference associated with the input signal.
TC530/TC534 INITIALIZATION AND LOAD VALUE WRITE CYCLE
Power-up RESET
Conversion
Phase
R/W
Input Multiplexer (TC534 Only)
Undefined
Write LOAD VALUE to Serial Port
AZ
INT
AZ
R/W brought LOW during AZ
for serial port write cycle
Converter held in AZ
state due to RESET = 1
Converter in Normal Service
DINT
IZ
AZ…
Continuous Conversions
R/W = HIGH strobes
LOAD VALUE into
timebase and starts
conversion
RESET
DCLK
DIN
1
1
MSB
EOC
5.7
0 0 1 1
LOAD VALUE
1
1
LSB
DC/DC Converter
An on-board, TC7660H-type charge pump supplies
negative bias to the converter circuitry, as well as to
external devices. The charge pump develops a negative output voltage by moving charge from the power
supply to the reservoir capacitor at VSS by way of the
commutating capacitor connected to the CAP+ and
CAP- inputs.
The charge pump clock operates at a typical frequency
of 100kHz. If lower quiescent current is desired, the
charge pump clock can be slowed by connecting an
external capacitor from the OSC pin to VDD. Reference
typical characteristics curves.
DS21433B-page 14
 2002 Microchip Technology Inc.
TC530/TC534
6.0
TYPICAL CHARACTERISTICS
The graphs and tables following this note are a statistical summary based on a limited number of samples and are
provided for informational purposes only. The performance characteristics listed herein are not tested or guaranteed.
In some graphs or tables, the data presented may be outside the specified operating range (e.g., outside specified
power supply range), and therefore outside the warranted range.
Output Voltage vs. Output Current
Output Voltage vs. Load Current
5
TA = 25˚C
V+ = 5V
3
2
1
0
-1
-2
Slope 60Ω
-3
-2
-3
-4
-5
-6
-4
-7
-5
-8
0
10
TA = 25˚C
-1
OUTPUT VOLTAGE (V)
4
OUTPUT VOLTAGE (V)
-0
20
30
40
50
60
70
0
80
2
4
Output Ripple vs. Load Current
OUTPUT SOURCE RESISTANCE (Ω)
OUTPUT RIPPLE (mV PK-PK)
V+ = 5V, TA = 25˚C
Osc. Freq. = 100kHz
150
CAP = 1µF
125
100
CAP = 10µF
75
50
25
0
0
1
2
3
4
5
6
7
8
9
10
100
90
10
12
14
60
50
40
0
25
50
TEMPERATURE (˚C)
-25
10
1
OSCILLATOR CAPACITANCE (pF)
1000
OSCILLATOR FREQUENCY (kHz)
TA = +25˚C
V+ = 5V
100
75
100
Oscillator Frequency vs. Temperature
150
 2002 Microchip Technology Inc.
20
70
Oscillator Frequency vs. Capacitance
10
18
80
-50
100
1
16
V+ = 5V
IOUT = 10mA
LOAD CURRENT (mA)
OSCILLATOR FREQUENCY (kHz)
8
Output Source Resistance vs. Temperature
200
175
6
OUTPUT CURRENT (mA)
LOAD CURRENT (mA)
V+ = 5V
125
100
75
50
-50
-25
0
25
75
50
TEMPERATURE (˚C)
100
125
DS21433B-page 15
TC530/TC534
7.0
PACKAGING INFORMATION
7.1
Package Marking Information
Package marking data not available at this time.
7.2
Taping Forms
Component Taping Orientation for 28-Pin SOIC (Wide) Devices
User Direction of Feed
PIN 1
W
P
Standard Reel Component Orientation
for TR Suffix Device
Carrier Tape, Number of Components Per Reel and Reel Size
Package
28-Pin SOIC (W)
Carrier Width (W)
Pitch (P)
Part Per Full Reel
Reel Size
24 mm
12 mm
1000
13 in
Component Taping Orientation for 44-Pin PQFP Devices
User Direction of Feed
PIN 1
W
P
Standard Reel Component Orientation
for TR Suffix Device
Carrier Tape, Number of Components Per Reel and Reel Size
Package
44-Pin PQFP
Carrier Width (W)
Pitch (P)
Part Per Full Reel
Reel Size
24 mm
16 mm
500
13 in
NOTE: Drawing does not represent total number of pins.
DS21433B-page 16
 2002 Microchip Technology Inc.
TC530/TC534
7.3
Package Dimensions
28-Pin PDIP (Narrow)
PIN 1
.288 (7.32)
.240 (6.10)
.045 (1.14)
.030 (0.76)
.310 (7.87)
.290 (7.37)
1.400 (35.56)
1.345 (34.16)
.200 (5.08)
.140 (3.56)
.040 (1.02)
.015 (0.38)
.150 (3.81)
.115 (2.92)
.110 (2.79)
.090 (2.29)
.070 (1.78)
.045 (1.14)
.015 (0.38)
.008 (0.20)
3˚ MIN.
.400 (10.16)
.310 (7.87)
.022 (0.56)
.015 (0.38)
Dimensions: inches (mm)
40-Pin PDIP (Wide)
PIN 1
.555 (14.10)
.530 (13.46)
2.065 (52.45)
2.027 (51.49)
.610 (15.49)
.590 (14.99)
.200 (5.08)
.140 (3.56)
.040 (1.02)
.020 (0.51)
.150 (3.81)
.115 (2.92)
.110 (2.79)
.090 (2.29)
.070 (1.78)
.045 (1.14)
.015 (0.38)
.008 (0.20)
3˚ MIN.
.700 (17.78)
.610 (15.50)
.022 (0.56)
.015 (0.38)
Dimensions: inches (mm)
 2002 Microchip Technology Inc.
DS21433B-page 17
TC530/TC534
7.3
Package Dimensions (Continued)
28-Pin SOIC (Wide)
PIN 1
.299 (7.59) .419 (10.65)
.291 (7.40) .398 (10.10)
.713 (18.11)
.697 (17.70)
.103 (2.62)
.097 (2.46)
.019 (0.48)
.014 (0.36)
.013 (0.33)
.009 (0.23)
8˚ MAX.
.012 (0.30)
.004 (0.10)
.050 (1.27)
.016 (0.40)
Dimensions: inches (mm)
44-Pin PQFP
7 ˚MAX.
.009 (0.23)
.005 (0.13)
PIN 1
.018 (0.45)
.012 (0.30)
.041 (1.03)
.026 (0.65)
.398 (10.10)
.390 (9.90)
.557 (14.15)
.537 (13.65)
.031 (0.80) TYP.
.398 (10.10)
.390 (9.90)
.557 (14.15)
.537 (13.65)
.010 (0.25) TYP.
.083 (2.10)
.075 (1.90)
.096 (2.45) MAX.
Dimensions: inches (mm)
DS21433B-page 18
 2002 Microchip Technology Inc.
TC530/534
SALES AND SUPPORT
Data Sheets
Products supported by a preliminary Data Sheet may have an errata sheet describing minor operational differences and recommended workarounds. To determine if an errata sheet exists for a particular device, please contact one of the following:
1.
2.
3.
Your local Microchip sales office
The Microchip Corporate Literature Center U.S. FAX: (480) 792-7277
The Microchip Worldwide Site (www.microchip.com)
Please specify which device, revision of silicon and Data Sheet (include Literature #) you are using.
New Customer Notification System
Register on our web site (www.microchip.com/cn) to receive the most current information on our products.
 2002 Microchip Technology Inc.
DS21433B-page 19
TC530/534
NOTES:
DS21433B-page 20
 2002 Microchip Technology Inc.
TC530/TC534
Information contained in this publication regarding device
applications and the like is intended through suggestion only
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
No representation or warranty is given and no liability is
assumed by Microchip Technology Incorporated with respect
to the accuracy or use of such information, or infringement of
patents or other intellectual property rights arising from such
use or otherwise. Use of Microchip’s products as critical components in life support systems is not authorized except with
express written approval by Microchip. No licenses are conveyed, implicitly or otherwise, under any intellectual property
rights.
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Solutions Company are registered trademarks of Microchip Technology Incorporated in the U.S.A. and other countries.
dsPIC, ECONOMONITOR, FanSense, FlexROM, fuzzyLAB,
In-Circuit Serial Programming, ICSP, ICEPIC, microPort,
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MXDEV, PICC, PICDEM, PICDEM.net, rfPIC, Select Mode
and Total Endurance are trademarks of Microchip Technology
Incorporated in the U.S.A.
Serialized Quick Turn Programming (SQTP) is a service mark
of Microchip Technology Incorporated in the U.S.A.
All other trademarks mentioned herein are property of their
respective companies.
© 2002, Microchip Technology Incorporated, Printed in the
U.S.A., All Rights Reserved.
Printed on recycled paper.
Microchip received QS-9000 quality system
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The Company’s quality system processes and
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 2002 Microchip Technology Inc.
DS21433B-page 21
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France
Microchip Technology SARL
Parc d’Activite du Moulin de Massy
43 Rue du Saule Trapu
Batiment A - ler Etage
91300 Massy, France
Tel: 33-1-69-53-63-20 Fax: 33-1-69-30-90-79
Germany
Microchip Technology GmbH
Gustav-Heinemann Ring 125
D-81739 Munich, Germany
Tel: 49-89-627-144 0 Fax: 49-89-627-144-44
Italy
Microchip Technology SRL
Centro Direzionale Colleoni
Palazzo Taurus 1 V. Le Colleoni 1
20041 Agrate Brianza
Milan, Italy
Tel: 39-039-65791-1 Fax: 39-039-6899883
United Kingdom
Microchip Ltd.
505 Eskdale Road
Winnersh Triangle
Wokingham
Berkshire, England RG41 5TU
Tel: 44 118 921 5869 Fax: 44-118 921-5820
04/20/02
*DS21433B*
DS21433B-page 22
 2002 Microchip Technology Inc.