Description
The 970980A-35.61/KF Ka-Band Up-Downconverter is a precision RF signal conversion solution designed for fixed-frequency Ka-band systems operating at 35.61 GHz. This unit integrates both upconversion and downconversion functions within a single platform, enabling bidirectional frequency translation between Ka-band RF and IF frequencies from 4 to 5.5 GHz.
Engineered for applications requiring exceptional frequency stability and spectral control, the 970980A-35.61/KF supports a 600 MHz operational bandwidth and utilizes a highly stable LO architecture with 50 ppb or better frequency stability. The converter supports both internal LO operation and an optional externally fed LO, with external LO power levels from 0 to 6 dBm. A built-in provision allows ±100 kHz LO frequency sweep around the selected LO frequency, supporting fine system alignment and testing.
On the upconversion path, the unit accepts IF input levels from −45 to −20 dBm, delivering Ka-band RF output power from 0 to 6 dBm with 1 dB peak-to-peak gain flatness and harmonic suppression of 20 dBc. The downconversion path supports RF input power levels from 0 to −20 dBm, with IF output levels adjustable between −10 and +10 dBm, enabling flexible interfacing with downstream receivers and digitizers.
The 970980A-35.61/KF is housed in a 19-inch chassis and operates from a ~230 VAC, 50 Hz power supply, making it well suited for laboratory, ground-based, and fixed-infrastructure installations. RF and LO interfaces use K-type coaxial connectors, while IF interfaces are provided via N-type coaxial connectors, ensuring reliable performance at Ka-band frequencies.
This Ka-band up-downconverter is well suited for radar systems, Ka-band communication links, test and measurement platforms, and scientific or sensing applications where bidirectional frequency translation, tight frequency stability, and repeatable RF performance are required.
*All data presented is collected from a sample lot.
* Actual data may vary unit to unit, slightly.
*All testing was performed under +25 °C case temperature.
*Consult factory to confirm if material, plating, size, shape, orientation and any electrical parameter is critical for the application as website information is for reference only.
*Millimeter Wave Products, Inc. reserves the right to change the information presented on website without notice as we continue to enhance the performance and design of our products.
Key Specifications (Summary)
RF Input / Output Frequency: 35.61 GHz (Ka-band)
Operational Bandwidth: 600 MHz
IF Frequency Range: 4 – 5.5 GHz
IF Connector: N-Type (Female)
RF Connector: K-Type (Female)
Upconverter Performance
Upconverter IF Input Power Range: −45 dBm to −20 dBm
RF Output Power Level: 0 dBm to 6 dBm
P1dB (IF Input): −5 dBm
Gain Flatness (Peak-to-Peak): 1 dB
Downconverter Performance
Downconverter RF Input Power Range: 0 dBm to −20 dBm
IF Output Power Level: −10 dBm to 10 dBm
P1dB (RF Input): 15 dBm
Gain Flatness (Peak-to-Peak): 1 dB
Local Oscillator (LO) Characteristics
LO Source: Internal VCO with optional external LO feed (externally/mechanically switchable)
External LO Input Power: 0 dBm to 6 dBm
External LO Frequency: TBD
VCO Control Voltage: 0 – 5 V
LO Frequency Stability: 50 ppb or better
LO Fine Tuning Capability: ±100 kHz sweep around selected LO frequency
Phase, Spurs, and Linearity
Harmonics: −20 dBc
Spectral Performance: Optimized for stable Ka-band up/downconversion
Mechanical and Power
Chassis Size: 19-inch
Operating Temperature: 0°C to +40°C
Power Supply: ~230 VAC, 50 Hz
RF Frequency Conversion Calculator (GHz)
Calculate RF and image frequencies for RF upconverters and downconverters using GHz units.
Formulas
- High-side LO: RF = LO + IF, Image = LO − IF
- Low-side LO: RF = LO − IF, Image = LO + IF
Image Frequency Calculator (GHz)
Calculate the image frequency for a mixer/downconverter using LO and IF in GHz.
How it works
- Desired RF: LO ± IF (depends on side)
- Image RF: LO ∓ IF (opposite side from desired)
- Separation between desired and image: 2 × IF
Conversion Gain & Output Power Calculator (dBm)
Calculate output power for RF upconverters, downconverters, and frequency conversion chains using dBm and dB.
Formula
- Pout (dBm) = Pin + Conversion Gain + Amplifier Gain − Attenuation
- Net Gain (dB) = Conversion Gain + Amplifier Gain − Attenuation
Cascaded Noise Figure Calculator (Friis)
Calculate total receiver noise figure and total gain for LNA + downconverter + IF stages using Friis.
Formulas (Friis)
- Convert NF(dB) to noise factor: F = 10^(NF/10)
- Convert Gain(dB) to linear: G = 10^(Gain/10)
- Total noise factor: Ftotal = F1 + (F2−1)/G1 + (F3−1)/(G1·G2) + (F4−1)/(G1·G2·G3)
- Total NF(dB) = 10·log10(Ftotal)
- Equivalent noise temperature: Te = (Ftotal−1)·T0, with T0 = 290 K
Frequency Stability Calculator (ppm/ppb → Hz)
Convert oscillator or LO stability (ppm/ppb) into frequency error at a given carrier frequency.
Formula
- Error (Hz) = Frequency (Hz) × Stability
- ppm = 1×10-6, ppb = 1×10-9
dBm ↔ Watts Converter
Convert RF power between dBm, Watts, milliWatts, and dBW for amplifiers, BUCs, and RF chains.
Formulas
- W = 10^((dBm − 30)/10)
- dBm = 10·log10(W) + 30
- dBW = dBm − 30
Free-Space Path Loss (FSPL) Calculator
Estimate free-space path loss for point-to-point links, SatCom, telemetry, and RF system planning.
Formula
- FSPL(dB) = 92.45 + 20·log10(fGHz) + 20·log10(dKm)
- Valid for free-space propagation (no atmospheric/terrain losses included)
RF Upconverter and Downconverter FAQ
These quick answers cover RF upconverters, RF downconverters, BUCs, LNBs, and frequency conversion specs used in satellite communications (SatCom), point-to-point microwave links, radar, telemetry, test and measurement, and 5G/mmWave systems.
Quick Answers
What does an RF upconverter do?
An RF upconverter translates a lower-frequency signal, such as IF or L-band, to a higher RF or microwave frequency so it can be transmitted by an antenna. In many transmit chains, the upconverter is followed by an RF power amplifier; when integrated, it is often called a Block Upconverter (BUC).
What does an RF downconverter do?
An RF downconverter converts a high-frequency RF input to a lower intermediate frequency (IF) that is easier to filter, amplify, digitize, and demodulate. In receiver front ends, a downconverter is often paired with an LNA; when integrated, it is commonly called an LNB (Low-Noise Block downconverter).
What is the difference between a BUC and an RF upconverter?
A BUC combines an RF upconverter with an integrated power amplifier to deliver higher output power for satellite uplinks and other transmit applications. An RF upconverter alone performs frequency translation but may not include the high-power amplification stage.
What IF frequencies are commonly used in RF systems?
Common IF frequencies include 70 MHz and 140 MHz, plus L-band IF ranges such as 950–2150 MHz. The best IF depends on the modem interface, channel plan, filtering requirements, and the overall superheterodyne architecture.
Why is image rejection important in frequency converters?
Image rejection suppresses unwanted signals that can downconvert to the same IF as the desired signal during mixing. Higher image rejection improves receiver sensitivity, reduces interference, and helps maintain spectral purity in dense RF environments.
More Technical Questions
What is an image frequency in a mixer or downconverter?
What is LO leakage and why does it matter?
What does low phase noise mean for RF upconverters and downconverters?
Why is a 10 MHz reference input used?
What is conversion gain, and how do gain control and digital attenuation help?
What does AGC do in a frequency conversion chain?
What is instantaneous bandwidth?
Where are RF frequency converters used?
Glossary of RF Frequency Converter Specification Terms
Core Frequency Conversion Terms
Upconversion
The process of translating a lower-frequency signal, such as IF or L-band, to a higher RF or millimeter-wave frequency using a mixer and local oscillator. Upconversion is used in transmit chains for satellite communication, radar, telemetry, and wireless systems.
Downconversion
The process of translating a high-frequency RF or millimeter-wave signal to a lower intermediate frequency for filtering, amplification, digitization, or demodulation. Downconversion is fundamental in receiver architectures.
Up-Downconverter
A frequency conversion device that integrates both upconversion and downconversion functions within a single unit, enabling bidirectional frequency translation between RF and IF stages.
Frequency Converter
A general RF component that performs upconversion, downconversion, or both, enabling frequency translation between IF, RF, and millimeter-wave bands.
Intermediate Frequency (IF)
A standardized frequency used between RF and baseband stages to simplify filtering, amplification, and signal processing. Common IF ranges include 70 MHz, 140 MHz, 950–1450 MHz, 950–2150 MHz, and 4–12 GHz.
RF Frequency
The operating radio frequency after conversion. In Mi-Wave 970 / 980 series products, RF frequencies commonly span X-band through Ku-, Ka-, Q-, and V-band.
Local Oscillator (LO) and Mixing Terms
Local Oscillator (LO)
A stable signal source used in a mixer to enable frequency translation. LO quality directly impacts phase noise, spurious performance, and frequency stability.
External LO Input
An externally supplied LO signal used to lock the converter to a system reference, improving synchronization and frequency accuracy across multiple devices.
LO Leakage
Unwanted LO energy appearing at the RF or IF ports. Low LO leakage reduces spurious emissions and interference.
Image Frequency
An undesired frequency that also converts to the same IF during mixing and must be suppressed through filtering or image-reject architectures.
Image Rejection
The ability of a frequency converter to suppress unwanted image frequencies. High image rejection improves receiver sensitivity and spectral purity.
Gain, Power, and Linearity Specifications
Conversion Gain
The net gain or loss introduced by the frequency conversion process. Conversion gain may be fixed or adjustable depending on design.
Gain Flatness
The variation of conversion gain across the operating bandwidth. Low gain flatness variation ensures uniform signal amplitude.
Digital Attenuation
Digitally controlled attenuation used to adjust output or conversion gain in precise, repeatable steps.
Automatic Gain Control (AGC)
A control function that automatically adjusts gain or attenuation to maintain a consistent output level despite input signal variations.
P1dB (1 dB Compression Point)
The output power level at which gain compresses by 1 dB from linear operation. Indicates the usable linear power range of the converter.
Output Power
The RF power level available at the output of an upconverter or the IF output of a downconverter.
OIP3 (Output Third-Order Intercept Point)
A measure of linearity indicating how well the device handles multiple signals without generating intermodulation distortion.
Noise and Signal Quality Metrics
Noise Figure (NF)
A measure of how much noise a component adds to the signal. Low noise figure is critical in downconverters and receiver front ends.
Phase Noise
Short-term frequency fluctuations of the LO or output signal, typically expressed in dBc/Hz. Low phase noise supports high-order modulation and radar resolution.
Frequency Stability
The ability of a converter or LO to maintain accurate frequency over time, temperature, and environmental conditions.
Reference Input
An external frequency reference, commonly 10 MHz, used to lock the LO and synchronize multiple RF systems.
Bandwidth and Channel Characteristics
Instantaneous Bandwidth
The frequency range over which the converter operates at a single tuning setting without retuning.
Operational Bandwidth
The total frequency span supported by the converter across its tuning range.
Tuning Resolution (Step Size)
The smallest frequency increment by which the LO or output frequency can be adjusted.
Multichannel Operation
A configuration where multiple independent frequency conversion paths operate in parallel within a single unit.
Spurious and Spectral Performance
Spurious Responses (Spurs)
Unwanted discrete frequency components generated by mixing products, harmonics, or nonlinearities.
Signal-Related Spurious
Spurious signals directly related to the input or output signal frequency.
Non-Signal-Related Spurious
Spurious emissions not directly tied to the signal frequency, often caused by internal oscillators or digital circuitry.
Harmonic Suppression
The attenuation of harmonic frequencies generated by nonlinear RF components.
Spectral Purity
The cleanliness of the output spectrum, characterized by low phase noise, low spurious content, and strong image suppression.
Interfaces, Packaging, and Integration
WR-Waveguide Interface
A standardized rectangular waveguide used for millimeter-wave RF interfaces, such as WR-28 (Ka-band) or WR-22 (Q-band).
Coaxial IF Interface
A coaxial connector, such as SMA or N-type, used for IF input or output connections.
Coupled Test Port
A low-level monitoring output that allows signal verification without interrupting the main RF path.
Commercial Rack-Mount Packaging
An enclosure designed for indoor laboratory, test, and ground-station installations.
Ruggedized or Environmental Packaging
Sealed or reinforced enclosures designed for outdoor, airborne, or harsh operating environments.
System-Level Terms
Receiver Front-End Protection
The use of frequency converters and filtering to prevent strong signals from overloading LNAs and mixers.
Dynamic Range
The range between the smallest and largest signal levels that can be processed without excessive noise or distortion.
Synchronization
The alignment of frequency and phase across multiple converters or channels using a common reference.
Regulatory Compliance
Ensuring frequency-converted signals meet emission limits and spectral mask requirements imposed by regulatory authorities.
| Model Number | Band | Description | Frequency (GHz) | Converter Type | # of Channels | Packaging | User Preferences | LINK |
|---|---|---|---|---|---|---|---|---|
| 980-10/385S | C, S, X | Upconverter | 2-18 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 980A-34.5/381 S | Ka | Upconverter | 26.5-40 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970980A-35.61 /KF | Ka | Up-Downconverter | 35.61 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970B-38.25/383S | Q | Downconverter | 38.0-38.5 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970A-39.65/599 | Ka | Downconverter | 39.4-39.9 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 980B-43.25/383S | Q | Upconverter | 42.0-43.5 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970U-47.2/51 .4/1.85mmF | U | Downconverter | 47.2-51.4 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970980U B-47.2/51 .4/1.85mmF-PLO | U | Up-Downconverter | 47.2-51.4 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970V-62.5/385 | V | Downconverter | 70-65 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970E-70.4/86.4/387 | E | Downconverter | 70.4-86.4 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC | |
| 970980W-20/387S | W | Up-Downconverter | 95-100 | Synthesized | Block | 1,2,3,4 | Commercial Rack Environmental | Bandwidth Internal/External Ref Digital Attenuation AGC |
RF Upconverters and Downconverters
Applications for Ka-Band Up-Downconverter (970980A-35.61/KF)
The 970980A-35.61/KF Ka-Band Up-Downconverter is designed for systems requiring bidirectional frequency translation at a fixed Ka-band frequency, with tight frequency control and stable long-term performance. Its integrated upconversion and downconversion architecture simplifies system design while maintaining high signal integrity.
Radar and Sensing Systems
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Ka-band radar transmit and receive chains
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FMCW and CW radar architectures
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Ground-based and laboratory radar platforms
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Target detection, tracking, and characterization systems
High frequency stability and controlled gain flatness support accurate range and Doppler measurements.
RF and Millimeter-Wave Test & Measurement
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Ka-band signal generation and analysis
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Receiver sensitivity and dynamic range testing
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System calibration and verification
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Automated test equipment (ATE) environments
Bidirectional conversion enables streamlined testing without reconfiguring external signal chains.
Scientific and Research Applications
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Remote sensing and atmospheric research
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University and government research laboratories
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Experimental Ka-band communication and sensing platforms
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Long-duration monitoring and spectral analysis
Stable LO performance and narrowband operation support precision measurements.
Ka-Band Communication Links
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Fixed-frequency Ka-band communication systems
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Experimental and prototype Ka-band links
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Ground-based communication testbeds
The integrated up-downconversion architecture supports compact, repeatable system designs.
Build Your RF Upconverter or Downconverter Needs and more!
Our team brings over 35 years of experience in the microwave and millimeter-wave RF industry, spanning design, prototyping, manufacturing, and system integration. We work closely with customers to help turn concepts into production-ready solutions, supporting a wide range of RF technologies. Contact us today to discuss RF upconverters, RF downconverters, transceivers, LNBs, low noise block upconverters, and custom RF sub-assembly systems.
Mi-Wave has designed, built, and supported numerous custom RF and millimeter-wave projects that require upconverters, downconverters, and integrated RF components within complex systems. From initial design and prototyping through full-scale manufacturing, our team supports every step of the development process. Contact us to discuss your project requirements and let Mi-Wave help engineer, manufacture, and deliver your RF assemblies with confidence.
