參數(shù)資料
型號: ALD500RA
廠商: Advanced Linear Devices, Inc.
英文描述: PRECISION INTEGRATING ANALOG PROCESSOR WITH PRECISION VOLTAGE REFERENCE
中文描述: 精密集成了模擬處理器,高精度電壓基準
文件頁數(shù): 8/12頁
文件大?。?/td> 93K
代理商: ALD500RA
8
Advanced Linear Devices
ALD500RAU/ALD500RA/ALD500R
ALD500RAU/ALD500RA/ALD500R CONVERSION CYCLE
The ALD500RAU/ALD500RA/ALD500R conversion cycle
takes place in four distinct phases, the Auto Zero Phase, the
Input Signal Integration Phase, the Reference Voltage
Deintegration Phase, and the Integrator Zero Phase. A typical
measurement cycle uses all four phases in an order sequence
as mentioned above. The internal analog switch status for
each of these phases is summarized in Table 1.
The following is a detailed description of each one of the four
phases of the conversion cycle.
Auto Zero Phase (AZ Phase)
The analog-to-digital conversion cycle begins with the Auto
Zero Phase, when the digital controller applies low logic level
to input A and high logic level to input B of the analog
processor. During this phase, the reference voltage is stored
on reference capacitor C
REF
, comparator offset voltage and
the sum of the buffer and integrator offset voltages are stored
on auto zero capacitor C
AZ
. During the Auto Zero Phase, the
comparator output is characterized by an indeterminate
waveform.
During the Auto Zero Phase, the external input signal is
disconnected from the internal circuitry of the ALD500RAU/
ALD500RA/ALD500R by opening the two SW
IN
analog
switches and connecting the internal input nodes internally to
analog ground. A feedback loop, closed around the integrator
and comparator, charges the C
AZ
capacitor with a voltage to
compensate for buffer amplifier, integrator and comparator
offset voltages.
This is the system initialization phase, when a conversion is
ready to be initiated at system turn-on. In practice the
converter can be operated in continuous conversion mode,
where AZ phase must be long enough for the circuit conditions
to settle out any system errors. Typically this phase is set to
be equal to t
INT
.
Input Signal Integration Phase (INT Phase)
During the Input Signal Integration Phase (INT), the
ALD500RAU/ALD500RA/ALD500R integrates the differential
voltage across the (V
+IN
) and (V
-IN
) inputs. The differential
voltage must be within the device's common-mode voltage
range CMVR. The integrator charges C
INT
for a fixed period
of time, or counts a fixed number of clock pulses, at a rate
determined by the magnitude of the input voltage. During this
phase, the analog inputs see only the high impedance of the
noninverting operational amplifier input of the buffer. The
integrator responds only to the voltage difference between the
analog input terminals, thus providing true differential analog
inputs.
The input signal polarity is determined by software control at
the end of this phase: C
OUT
= 1 for positive input polarity;
C
OUT
= 0 for negative input polarity. The value is, in effect, the
sign bit for the overall conversion result.
The duration of this phase is selected by design to be a fixed
time and depends on system parameters and component
value selections. The total number of clock pulses or clock
counts, during integration phase determine the resolution of
the conversion. For high resolution applications, this total
number of clock pulses should be maximized. The basic unit
of resolution is in
μ
V/count. Before the end of this phase,
comparator output is sampled by the microcontroller. This
phase is terminated by changing logic inputs AB from 10 to 11.
Reference Voltage Deintegration Phase (D
INT
Phase)
At the end of the Input Signal Integration Phase, Reference
Voltage Deintegration Phase begins. The previously charged
reference capacitor is connected with the proper polarity to
ramp the integrator output back to zero. The ALD500RAU/
ALD500RA/ALD500R analog processors automatically selects
the proper logic state to cause the integrator to ramp back
toward zero at a rate proportional to the reference voltage
stored on the reference capacitor. The time required to return
to zero is measured by the counter in the digital processor
using the same crystal oscillator. The phase is terminated by
the comparator output after the comparator senses when the
integrator output crosses zero. The counter contents are then
transferred to the register. The resulting time measurement
is proportional to the magnitude of the applied input voltage.
The duration of this phase is precisely measured from the
transition of AB from 10 to 11 to the falling edge of the
comparator output, usually with a crystal controlled digital
counter chain. The comparator delay contributes some error
in this phase. The typical comparator delay is 1
μ
sec
. The
comparator delay and overshoot will result in error timing,
which translates into error voltages. This error can be zeroed
and minimized during Integrator Output Zero Phase and
corrected in software, to within
±
1 count of the crystal clock
(which is equivalent to within
±
1 LSB, when 1 clock pulse = 1
LSB).
Integrator Zero Phase ( I
NTZ
Phase)
This phase guarantees the integrator output is at 0V when the
Auto Zero phase is entered, and that only system offset
voltages are compensated. This phase is used at the end of
the reference voltage deintegration and is used for applications
with high resolutions. If this phase is not used, the value of the
Auto-Zero capacitor (C
AZ
) must be much greater than the
value of the integration capacitor (C
INT
) to reduce the effects
of charge-sharing. The Integrator Zero phase should be
programmed to operate until the Output of the Comparator
returns "HIGH". A typical Integrator Zero Phase lasts 1msec.
The comparator delay and the controller's response latency
may result in Overshoot causing charge buildup on the
integrator at the end of a conversion. This charge must be
removed or performance will degrade. The Integrator Output
Zero phase should be activated (AB = 00) until C
OUT
goes
high. At this point, the integrator output is near zero. Auto Zero
Phase should be entered (AB = 01) and the ALD500RAU/
ALD500RA/ALD500R is held in this state until the next
conversion cycle.
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相關代理商/技術參數(shù)
參數(shù)描述
ALD500RA-10PE 制造商:ALD 制造商全稱:Advanced Linear Devices 功能描述:PRECISION INTEGRATING ANALOG PROCESSOR WITH PRECISION VOLTAGE REFERENCE
ALD500RA-10PEL 功能描述:模數(shù)轉換器 - ADC 17 Bt A/D w10 ppm VR RoHS:否 制造商:Texas Instruments 通道數(shù)量:2 結構:Sigma-Delta 轉換速率:125 SPs to 8 KSPs 分辨率:24 bit 輸入類型:Differential 信噪比:107 dB 接口類型:SPI 工作電源電壓:1.7 V to 3.6 V, 2.7 V to 5.25 V 最大工作溫度:+ 85 C 安裝風格:SMD/SMT 封裝 / 箱體:VQFN-32
ALD500RA-10QE 制造商:ALD 制造商全稱:Advanced Linear Devices 功能描述:PRECISION INTEGRATING ANALOG PROCESSOR WITH PRECISION VOLTAGE REFERENCE
ALD500RA-10QEL 功能描述:模數(shù)轉換器 - ADC 17 Bit A/D w10ppm VR RoHS:否 制造商:Texas Instruments 通道數(shù)量:2 結構:Sigma-Delta 轉換速率:125 SPs to 8 KSPs 分辨率:24 bit 輸入類型:Differential 信噪比:107 dB 接口類型:SPI 工作電源電壓:1.7 V to 3.6 V, 2.7 V to 5.25 V 最大工作溫度:+ 85 C 安裝風格:SMD/SMT 封裝 / 箱體:VQFN-32
ALD500RA-10SE 制造商:ALD 制造商全稱:Advanced Linear Devices 功能描述:PRECISION INTEGRATING ANALOG PROCESSOR WITH PRECISION VOLTAGE REFERENCE
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