Specifications
| Type | Description |
|---|---|
| Part Number | SN75LVCP601 |
| Manufacturer | Texas Instruments |
| Product Type | Operational Amplifier |
| Category | Signal Chain |
| Package / Case | WQFN (RTJ), 20 pins, 4.00 mm x 4.00 mm nominal body |
| Supported Data Rates | 1.5, 3, or 6 Gbps; SATA redriver operation |
| Number of Channels | 2; dual-channel, single-lane SATA redriver |
| Supply Voltage | 3.3 V; nominal operating supply |
| Supply Voltage Range | 3.0-3.6 V; recommended operating conditions |
| Coupling Capacitor | 12 nF; recommended operating conditions |
| Operating Free-Air Temperature | 0 to 85 °C; recommended operating conditions |
| Absolute Maximum Supply Voltage | -0.5 to 4 V; over operating free-air temperature range |
| Absolute Maximum Differential I/O Voltage | -0.5 to 4 V; over operating free-air temperature range |
| Absolute Maximum Control I/O Voltage | -0.5 to VCC + 0.5 V; over operating free-air temperature range |
| Storage Temperature | 150 °C max; absolute maximum rating |
| HBM ESD Rating | ±10000 V; ANSI/ESDA/JEDEC JS-001 |
| CDM ESD Rating | ±1500 V; JEDEC JESD22-C101 |
| Machine Model ESD Rating | ±200 V; JEDEC Standard 22, Test Method A115-A |
| Junction-to-Ambient Thermal Resistance | 38 °C/W; RTJ WQFN, 20 pins |
| Junction-to-Case Top Thermal Resistance | 40 °C/W; RTJ WQFN, 20 pins |
| Junction-to-Board Thermal Resistance | 10 °C/W; RTJ WQFN, 20 pins |
| Junction-to-Top Characterization Parameter | 0.5 °C/W; RTJ WQFN, 20 pins |
| Junction-to-Board Characterization Parameter | 0.9 °C/W; RTJ WQFN, 20 pins |
| Junction-to-Case Bottom Thermal Resistance | 15.2 °C/W; RTJ WQFN, 20 pins |
| Active Mode Power Dissipation | 215 mW typ, 288 mW max; DEWx=EN=VCC, EQx=DEx=NC, K28.5 pattern at 6 Gbps, VID=700 mVp-p |
| Standby Mode Power Dissipation | 5 mW typ; EN=0 V, DEWx=EQx=DEx=NC, K28.5 pattern at 6 Gbps, VID=700 mVp-p |
| Active Mode Supply Current | 65 mA typ, 80 mA max; EN=3.3 V, DEWx=0 V, EQx=DEx=NC, K28.5 pattern at 6 Gbps, VID=700 mVp-p |
| Auto Low-Power Mode Supply Current | 6.5 mA typ, 10 mA max; device enabled and auto low-power conditions met |
| Standby Mode Supply Current | 1 mA max; EN=0 V |
| Maximum Data Rate | 1 to 6 Gbps; electrical characteristics |
| Input OOB Threshold | 50 mVpp min, 78 mVpp typ, 150 mVpp max; f=750 MHz |
| OOB Differential Delta | 25 mV; out-of-band detector |
| OOB Common-Mode Delta | 50 mV; out-of-band detector |
| Control Input High Voltage | 1.4 V min; all control pins |
| Control Input Low Voltage | 0.5 V max; all control pins |
| Control Input Hysteresis | 115 mV typ; control logic inputs |
| High-Level Input Current | 30 µA typ; EQx, DEx = VCC |
| High-Level Input Current | 1 µA typ; EN, DEWx = VCC |
| Low-Level Input Current | -30 µA typ; EQx, DEx = GND |
| Low-Level Input Current | -10 µA typ; EN, DEWx = GND |
| Differential Input Impedance | 85 Ω min, 100 Ω typ, 115 Ω max; receiver AC/DC |
| Single-Ended Input Impedance | 40 Ω typ; receiver AC/DC |
| Receiver Common-Mode Voltage | 1.8 V typ; receiver AC/DC |
| Differential Input Voltage | 120 mVppd min, 1600 mVppd max; f=1.5 GHz and 3 GHz |
| Differential-Mode Return Loss | 18 dB min, 28 dB typ; f=150 MHz to 300 MHz |
| Differential-Mode Return Loss | 14 dB min, 17 dB typ; f=300 MHz to 600 MHz |
| Differential-Mode Return Loss | 10 dB min, 12 dB typ; f=600 MHz to 1.2 GHz |
| Differential-Mode Return Loss | 8 dB min, 9 dB typ; f=1.2 GHz to 2.4 GHz |
| Differential-Mode Return Loss | 3 dB min, 9 dB typ; f=2.4 GHz to 3 GHz |
| Differential-Mode Return Loss Slope | -13 dB/dec; f=300 MHz to 6 GHz |
| Common-Mode Return Loss | 5 dB min, 10 dB typ; f=150 MHz to 300 MHz |
| Common-Mode Return Loss | 5 dB min, 17 dB typ; f=300 MHz to 600 MHz |
| Common-Mode Return Loss | 2 dB min, 23 dB typ; f=600 MHz to 1.2 GHz |
| Common-Mode Return Loss | 1 dB min, 16 dB typ; f=1.2 GHz to 2.4 GHz |
| Common-Mode Return Loss | 1 dB min, 12 dB typ; f=2.4 GHz to 3 GHz |
| Input Impedance Balance | 30 dB min, 41 dB typ; f=150 MHz to 300 MHz |
| Input Impedance Balance | 30 dB min, 38 dB typ; f=300 MHz to 600 MHz |
| Input Impedance Balance | 20 dB min, 32 dB typ; f=600 MHz to 1.2 GHz |
| Input Impedance Balance | 10 dB min, 26 dB typ; f=1.2 GHz to 2.4 GHz |
| Input Impedance Balance | 10 dB min, 25 dB typ; f=2.4 GHz to 3 GHz |
| Input Impedance Balance | 4 dB min, 20 dB typ; f=3 GHz to 5 GHz |
| Input Impedance Balance | 4 dB min, 17 dB typ; f=5 GHz to 6.5 GHz |
| Datasheet Status | request_only |
Product Overview
The SN75LVCP601 is a Texas Instruments two-channel, single-lane SATA redriver for Signal_Chain designs requiring operation at 1.5, 3, or 6 Gbps. The device is specified for a nominal 3.3 V supply, with recommended operation across 3.0-3.6 V and a 0 to 85 °C operating free-air temperature range.
The device supports receiver AC/DC characteristics including 85 Ω minimum, 100 Ω typical, and 115 Ω maximum differential input impedance, 40 Ω typical single-ended input impedance, and 1.8 V typical receiver common-mode voltage. Differential input voltage is specified from 120 mVppd to 1600 mVppd at 1.5 GHz and 3 GHz.
Power modes include active operation at 65 mA typical and 80 mA maximum supply current, auto low-power operation at 6.5 mA typical and 10 mA maximum, and standby current up to 1 mA with EN at 0 V. The 20-pin WQFN (RTJ) package has a 4.00 mm x 4.00 mm nominal body and documented thermal resistance and characterization parameters for board-level assembly analysis.
Key Features
- Two-channel, single-lane SATA redriver architecture
- Supports 1.5, 3, and 6 Gbps SATA rates
- Nominal 3.3 V supply with 3.0-3.6 V range
- 0 to 85 °C recommended free-air operation
- Active supply current: 65 mA typical, 80 mA maximum
- Auto low-power supply current: 6.5 mA typical, 10 mA maximum
- Standby supply current up to 1 mA with EN low
- 100 Ω typical differential input impedance
- Input OOB threshold: 78 mVpp typical at 750 MHz
- 20-pin WQFN package, 4.00 mm x 4.00 mm body
Typical Applications
- SATA signal redriving
- Single-lane SATA links
- 6 Gbps SATA signal paths
- Dual-channel SATA routing
- SATA out-of-band detection designs
- 3.3 V Signal_Chain assemblies
- WQFN 20-pin board designs
Procurement Notes
When requesting a quote for SN75LVCP601, buyers should confirm the manufacturer, package or case, required quantity, target date code, compliance documents, packing method, destination country and expected delivery schedule.
If alternatives are acceptable, buyers should share the approved vendor list, required electrical or optical limits, package constraints and qualification requirements. Any alternative part should be reviewed by the buyer's engineering team before production use.
For analog and signal-chain sourcing, supply voltage, bandwidth, accuracy, noise level, package, temperature grade, input/output configuration and qualification requirements should be verified before approval.
FAQ
What data rates does the SN75LVCP601 support?
The SN75LVCP601 supports SATA redriver operation at 1.5, 3, or 6 Gbps. Its electrical characteristics list a maximum data-rate range of 1 to 6 Gbps.
What supply range is recommended for this device?
The device has a nominal operating supply of 3.3 V. The recommended supply-voltage range is 3.0-3.6 V, with recommended operation over 0 to 85 °C free-air temperature.
What package is used for the SN75LVCP601?
The SN75LVCP601 is supplied in an RTJ WQFN package with 20 pins and a 4.00 mm x 4.00 mm nominal body. Thermal data is specified for the RTJ WQFN 20-pin package.
What are the listed power modes?
The extracted electrical data lists active mode, auto low-power mode, and standby mode. Active supply current is 65 mA typical and 80 mA maximum, while standby current is 1 mA maximum with EN at 0 V.
Technical Review & Sourcing Note
Prepared by LDeepAI Component Sourcing Team. Reviewed for RFQ, documentation and alternative sourcing use. Last updated: June 30, 2026.
This page is based on manufacturer datasheet information and LDeepAI sourcing review. Specifications should be verified against the official manufacturer datasheet before final procurement or design approval. Final electrical, optical and reliability approval should be confirmed by the buyer's engineering team.