8-10 bit SAR ADC TSMC
Overview
The agileADC analog-to-digital converter is a traditional Charge-Redistribution SAR ADC that is referenced to VDD, VSS. The architecture can achieve up to 10-bit resolution at sample rates up to 20 MSps. It includes an eight-channel input multiplexor. Some inputs will be buffered inside the ADC, whereas others will bypass the buffer and be connected directly to the ADC to provide full rail-to-rail capability.
Key Features
- Resolution: 8b, 10b
- Sampling Rate (Fs): 1 Msps to 20Msps
- Input Signal Bandwidth: Fs/2
- SINAD1: Typ 54dB
- SFDR1: Typ -60dBc
- CMRR2: min 65dB
- PSSR1: Typ 30dB
- Monotonic and no missing codes
- Customisable design for simple SoC integration
- Integrated Calibration Mode
- Silicon Area – Please contact Agile Analog
Benefits
- DFT/DFM
- - AMBA-APB Interface to simply test and operation
- - Incorporated Trim and Calibration to facilitate process and/or manufacturing offsets to be adjusted
- - Built-in test mode
- Configurable Inputs
- - Up to 8 input channels
- - Buffer or unbuffered
- - Differential or Single-ended
- - Rail-to-Rail input
Block Diagram
Applications
- IoT, Security, Automotive, AI, SoCs, ASICs
Deliverables
- Datasheet
- Design Report
- Integration Guide
- Test Guide
- Integration model
- Tapeout Checklist
- Physical Verification Report
- Functional models
- Timing model (.LIB)
- Layout Floorplanning (LEF)
- Netlist (CDL)
- Layout (GDSII)
Technical Specifications
Foundry, Node
TSMC
Maturity
Available on request
Availability
Now
TSMC
In Production:
28nm
,
28nm
HPC
,
28nm
HPCP
,
180nm
,
180nm
E
,
180nm
FG
,
180nm
G
,
180nm
LP
,
180nm
LV
,
180nm
ULL
Pre-Silicon: 22nm , 28nm , 28nm HP , 28nm HPC , 28nm HPCP , 28nm HPL , 28nm HPM , 28nm LP , 40nm G , 40nm LP , 45nm GS , 45nm LP , 55nm FL , 55nm G , 55nm GP , 55nm LP , 55nm NF , 55nm ULP , 55nm ULPEF , 55nm UP , 65nm G , 65nm GP , 65nm LP , 80nm , 80nm GT , 80nm HS , 85nm , 90nm FS , 90nm FT , 90nm G , 90nm GOD , 90nm GT , 90nm LP , 90nm zzz , 110nm G , 110nm HV , 110nm LVP , 130nm G , 130nm LP , 130nm LV , 130nm LVOD , 150nm G , 150nm LV , 160nm G , 160nm LP , 180nm E , 180nm ELL , 180nm FG , 180nm G , 180nm LP , 180nm LV , 180nm ULL
Silicon Proven: 28nm , 28nm HPC , 28nm HPCP , 180nm , 180nm E , 180nm ELL , 180nm FG , 180nm G , 180nm LP , 180nm LV , 180nm ULL
Pre-Silicon: 22nm , 28nm , 28nm HP , 28nm HPC , 28nm HPCP , 28nm HPL , 28nm HPM , 28nm LP , 40nm G , 40nm LP , 45nm GS , 45nm LP , 55nm FL , 55nm G , 55nm GP , 55nm LP , 55nm NF , 55nm ULP , 55nm ULPEF , 55nm UP , 65nm G , 65nm GP , 65nm LP , 80nm , 80nm GT , 80nm HS , 85nm , 90nm FS , 90nm FT , 90nm G , 90nm GOD , 90nm GT , 90nm LP , 90nm zzz , 110nm G , 110nm HV , 110nm LVP , 130nm G , 130nm LP , 130nm LV , 130nm LVOD , 150nm G , 150nm LV , 160nm G , 160nm LP , 180nm E , 180nm ELL , 180nm FG , 180nm G , 180nm LP , 180nm LV , 180nm ULL
Silicon Proven: 28nm , 28nm HPC , 28nm HPCP , 180nm , 180nm E , 180nm ELL , 180nm FG , 180nm G , 180nm LP , 180nm LV , 180nm ULL