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TSL1401 Linear Sensor Array With Hold Datasheet PDF Download

  • Contents

Catalog

Description

Functional Block Diagram

Detailed Description

Absolute Maximum Ratings†

Recommended Operating Conditions

Electrical Characteristics

Operating Characteristics

Typical Characteristics

Applications Information

TSL1401 Datasheet

TSL1401 Manufacturer

Using Warning

TSL1401 FAQ

 

Description

The TSL1401 linear sensor array consists of a 128 × 1 array of photodiodes, associated charge amplifier circuitry, and a pixel data-hold function that provides simultaneous-integration start and stop times for all pixels. The pixels measure 63.5 µm (H) by 55 µm (W) with 63.5-µm center-to-center spacing and 8.5-µm spacing between pixels. Operation is simplified by internal control logic that requires only a serial-input (SI) signal and a clock.

 

Functional Block Diagram

TSL1401 Functional Block Diagram

TSL1401 Functional Block Diagram

 

Terminal Functions

NAME NO. DESCRIPTION
AO 3 Analog output
CLK 2 Clock. The clock controls charge transfer, pixel output, and reset.
GND 6, 7 Ground (substrate). All voltages are referenced to the substrate.
NC 5, 8 No internal connection
SI 1 Serial input. SI defines the start of the data-out sequence.
VDD 4 Supply voltage. Supply voltage for both analog and digital circuits.

 

Detailed Description

The sensor consists of 128 photodiodes arranged in a linear array. Light energy impinging on a photodiode generates photocurrent, which is integrated by the active integration circuitry associated with that pixel.

 

During the integration period, a sampling capacitor connects to the output of the integrator through an analog switch. The amount of charge accumulated at each pixel is directly proportional to the light intensity and the integration time.

 

The output and reset of the integrators is controlled by a 128-bit shift register and reset logic. An output cycle is initiated by clock ing in a logic 1 on SI. This causes all 128 sampling capacitors to be disconnected from their respective integrators and starts an integrator reset period. As the SI pulse is clocked through the shift register, the charge stored on the sampling capacitors is sequentially connected to a charge-coupled output amplifier that generates a voltage on analog output AO. The integrator reset period ends 18 clock cycles after the SI pulse is clocked in. Then the next integration period begins.

 

AO is driven by a source follower that requires an external pulldown resistor. When the output is not in the output phase, it is in a high-impedance state. The output is nominally 0 V for no light input and 2 V for a nominal full-scale output.

 

The TSL1401 is intended for use in a wide variety of applications, including: image scanning, mark and code reading, optical character recognition (OCR) and contact imaging, edge detection and positioning, and optical linear and rotary encoding.

 

Absolute Maximum Ratings†

Supply voltage, VDD: 7 V

Digital input current range, II: −20 mA to 20 mA

Operating free-air temperature range, TA: 0°C to 70°C

Storage temperature range, Tstg: −25°C to 85°C

Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds: 260°C

 

† 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.

 

(see Figure 1 and Figure 2)

  MIN NOM MAX UNIT
Supply voltage, VDD 4.5 5 5.5 V
Input voltage, VI 0   VDD V
High-level input voltage, VIH VDD × 0.7   VDD V
Low-level input voltage, VIL 0   VDD × 0.3 V
Wavelength of light source, λ 400   700 nm
Clock frequency, fclock 5   2000 kHz
Sensor integration time, tint 0.0645   100 ms
Setup time, serial input, tsu(SI) 0     ns
Hold time, serial input, th(SI) (see Note 1) 20     ns
Operating free-air temperature, TA 0   70

 

NOTE 1: SI must go low before the rising edge of the next clock pulse.

 

Figure 1. Timing Waveforms

Figure 1. Timing Waveforms

 

Electrical Characteristics

at fclock = 200 kHz, VDD = 5 V, TA = 25°C, λp = 565 nm, tint = 5 ms, RL = 330 Ω, Ee = 14 µW/cm2 (unless otherwise noted) (see Note 2)

PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
  Analog output voltage (white, average over 128 pixels)     1.8 2 2.2 V
  Analog output voltage (dark, average over 128 pixels) Ee = 0 0 0.1 0.2 V
PRNU Pixel response nonuniformity See Note 3   ±4% ±7.5%  
  Nonlinearity of analog output voltage See Note 4 ±0.4%     FS
  Output noise voltage See Note 5   1   mVrms
  Saturation exposure     136 175   nJ/cm2
  Analog output saturation voltage     3 3.5   V
DSNU Dark signal nonuniformity All pixels, See Note 6 Ee = 0   0.08 0.12 V
All except pixel 1, Ee = 0 See Note 6   0.017 0.035
IL Image lag See Note 7          
IDD Supply current       0.50%   mA
IIH High-level input current VI = VDD     2.5 4 μA
IIL Low-level input current VI = 0       1 μA
Ci Input capacitance       5 1 pF

 

NOTES: 

  1. Clock duty cycle is assumed to be 50%.
  2. PRNU is the maximum difference between the voltagefrom any single pixel and the average output voltage fromall pixels of the device under test when the array is uniformly illuminated.
  3. Nonlinearity is defined as the maximum deviation from abest-fit straight line over the dark-to-white irradiance levels,as a percent of analog output voltage (white).
  4. RMS noise is the standard deviation of a single-pixeloutput under constant illumination as observed over a5-second period.
  5. DNSU is the difference between the maximum andminimum of dark-current voltage.
  6. Image lag is a residual signal left in a pixel from aprevious exposure. It is defined as a percent of white-levelsignal remaining after a pixel is exposed to a white condition followed by a dark condition:

 

Operating Characteristics 

over recommended ranges of supply voltage and operating free-air temperature (see Figure 2)

PARAMETER TEST CONDITIONS MIN TYP UNIT
tw(H) Clock pulse duration (high)     50   ns
tw(L) Clock pulse duration (low)     50   ns
ts Analog output settling time to ± 1% RL = 330 Ω, CL = 50 pF   350 ns

 

Figure 2. Operational Waveforms

Figure 2. Operational Waveforms

 

Typical Characteristics

Figure 3. Photodiode Spectral Responsivity

Figure 3. Photodiode Spectral Responsivity

 

Applications Information

This dual-in-line package consists of a circuit mounted on a lead frame and encapsulated with an electrically nonconductive clear plastic compound.

 

Figure 4. Packaging Configuration

Figure 4. Packaging Configuration

 

† True position when unit is installed

NOTES:

  1. All linear dimensions are in inches andparenthetically in millimeters.
  2. This drawing is subject ot change without notice.

 

TSL1401 Datasheet

You can download the datasheet from the link given below:

TSL1401 Datasheet

 

TSL1401 Manufacturer

Texas Instruments Incorporated (TI) is an American technology company headquartered in Dallas, Texas, that designs and manufactures semiconductors and various integrated circuits, which it sells to electronics designers and manufacturers globally. It is one of the top 10 semiconductor companies worldwide based on sales volume.The company's focus is on developing analog chips and embedded processors, which account for more than 80% of its revenue.TI also produces TI digital light processing technology and education technology products including calculators, microcontrollers and multi-core processors. The company holds 45,000 patents worldwide as of 2016.

 

Using Warning

Note: Please check their parameters and pin configuration before replacing them in your circuit.

 

TSL1401 FAQ

What is linear sensor?

A Linear Transducer is a type of position sensor. Linear transducers measure linear displacement or movement along a single axis in any direction. They do this by converting the movement into an electrical signal which is proportional to the displacement so that it can be processed by various devices.

 

What are linear array sensors?

Linear array sensors consist of a linear array of integrating photosensing pixels which measure incident light over a user-defined exposure time and generate a voltage or digital output which represents the light exposure at each pixel. The sensors are available in a variety of lengths and pixel resolutions.

 

What is a sensor array used for?

A sensor array is a group of sensors, usually deployed in a certain geometry pattern, used for collecting and processing electromagnetic or acoustic signals.

 

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