Triangular Wave Generator Circuit

Triangular Wave Generator Circuit

This is a circuit for a constant amplitude triangular-wave generator. A variable frequency triangular wave whose amplitude is independent of frequency is provided by this circuit. This circuit is based on LM101.

Triangular Wave Generator Circuit

As a reset circuit, the generator embodies an integrator as a ramp generator and a threshold detector with hysteresis. There is no further explanation is needed because the integrator has been described in a previous section. It’s a latch circuit with a large dead zone, on that case, the threshold amplifier detector is similar to a Schmidt Trigger. By using positive feedback around an operational amplifier, we can implement this function. The positive feedback network provides a voltage at the non-inverting input which is determined by the attenuation of the feedback loop and the saturation voltage amplifier when the amplifier output is in either the positive or negative saturated state. The voltage at the input of the amplifier must be caused to change polarity by an amount in excess of the amplifier input offset voltage to cause the amplifier to change states. When this is done, until the voltage at its input again reverse, the amplifier saturates in the opposite direction and remains in that state. By examining the operation with the output of the threshold detector in the positive state, the complete circuit operation may be understood. To cause a current I+ to flow, we have to apply the detector positive saturation voltage to the integrator summing junction through the combination R3 and R4.

Then, a negative-going ramp with a rate of I+/C1 volts per second until its output equals the negative trip point of the threshold detector is generated by the integrator. After that, at the integrator summing point , the threshold detector changes to the negative output state and supplies a negative current, I-. A positive-going ramp with a rate of I-/C1 volts per second is generated by the integrator until its output equals the positive trip point of the threshold detector where the detector again changes output state and the cycle repeats. R3, R4, C1, and the positive and negative saturation voltages of the amplifier A1 determine the triangular-wave frequency. Amplitude is determined by the threshold detector saturation voltages and the ratio of R5 to the combination of R1 and R2. If the detector has equal positive and negative saturation voltages, positive and negative ramp rates are equal and positive and negative peaks are equal. If the inverting input of the threshold detector, A1, is offset with respect to ground, the output waveform may be offset with respect to ground. If the detector is clamped with matched Zener diodes as shown in following figure, the generator may be made independent of temperature and supply voltage. If power supply impedance causes oscillation during its transition time, the detector may be compensated and the integrator should be compensated for unity-gain. For maximum symmetry, the current into the integrator should be large with respect to Ibias and offset voltage should be small with respect to Voutpeak.



[Schematic circuit source: National Semiconductor Application Note]

Read More

No comments

Linearized Platinum RTD Signal Conditioner

The best choice for stability and high accuracy in temperature measurements is Platinum resistance temperature detectors (RTD). However, the signal conditioning is complicated by the RTD which exhibit a non-linear temperature versus resistance characteristic. The non-linearity amount of 0 C to 100 C is up to 0.4 C. Here is the schematic diagram of linearized platinum RTD signal conditioner :

This circuit use A1 as a negative gain inverter to drive a constant current across the platinum sensor. The current reference is provided by the 1oK resistor and LT1009. The self heating induced errors reduced and the voltage through the RTD is low because A1 operates at negative gain. The platinum sensor’s temperature varies A1’s output potential and fed to A2.




The offsetting and scaled gain are provided by A2. Therefore, the A2’s output will swing 0.00V to 10.000V for 0.00 C to 100.00 C temperature swing at the RTD. The noise pick-up is limited by the 1uF capacitor. Returning a small portion of the circuit’s output to A1 will correct the 0.4 C non linearity error due to the RTD’s imperfect response. This circuit is calibrated by substituting the sensor with a precision decade box. The deviation of the each sensor is different depends on the manufacture that produced it. The purity of the material fix the gain slope of the platinum. [Source: Linear Technology Application Note]

Read More

No comments

TV transmitter power amplifier design of the composition

R & D for the TV transmitter, the development of digital television transmitters focus transmitter power amplifier. TV transmitter in the clear demands of the power amplifier based on the analysis of the power amplifier and the main component of technical indicators and further study of the television transmitter power amplifier design, for our television transmission system for the development of certain research value.


Keywords: TV transmitter; PA; composition and design



1 Introduction



China’s major television stations in the analog transmitter is still the basic stage, the digital transmitter to the development work has just started. In the digital transmitter in general, digital television signals modulated by COFDM mode output frequency analog signals, amplified by the conversion into the part. The modulation, including IF-FT (8K) and IFFT (2K) modes, respectively 6817 and 1705 carriers, each carrier frequency spacing between the very close, so very easy to fall-modulation signal band, causing intermodulation distortion, linear amplifier will seriously affect poor digital transmitter of the key indicators MER (Modulation Error Rate) and the Shoulder (with shoulder). Therefore, the requirement to enlarge part of the linear state should be working on, to affect the signal quality. This content is produced according to the problem, study the basic television transmitter power amplifier module and the design of the corresponding program.



2 TV transmitter power amplifier overview



2.1 The basic requirements for TV transmitter power amplifier

Television broadcasting on the most basic requirement is that the transmitter power amplifier power gain should be high enough. Power amplifier is a broadband amplifier, can cover the entire UHF band, the launch of the channel changes without the need for by-channel adjustment, power amplifier modules at all levels of the most advanced solid-state amplification of imports. Basic requirements are: amplifiers with high linearity, wide dynamic range that the digital modulation signal peak in the dynamic range of the transmitter when there is still a good linearity; even if the defect in a state of the module, the transmitter can still broadcast; transmitter frequency should be high enough precision and frequency stability, low phase noise, to ensure that signals are transmitted at the lowest possible bit error rate and SNR.



2.2 TV Transmitter Power Amplifier Specifications

DVB_T terrestrial digital television transmitters in the conventional power amplifier of the specific indicator is as follows:

Frequency range: 470MHz to 860MHz; amplification by: AB linear amplification; input impedance: 50Ω; Output impedance: 50Ω; return loss: ≥ 15dB; input power: 1W (nominal); output power: 1000W (maximum); power input : 120VDC ± 15%; Power consumption: 1800W (maximum); RF input connector: N Head (Yam head); RF output interface: DIN7/16 head; Protection: RF reflected power is too large (≥ 50W), over current, overheating ; Cooling: Forced air cooling; ambient temperature: -5 ℃ to 45 ℃; Altitude: Up to 3000m; Weight: about 15kg.



2.3 Composition of TV transmitter power amplifier

DVB_T terrestrial digital TV transmitter in the main 500 (W) and 1000 (W), of which 500 (W) with two power amplifier modules, 1000 (w) has four power amplifier modules. Power amplifier generally includes the following nine modules: RF control module; 100W power amplifier module (RF drive level); four-way power divider; 270W power amplifier module (radio frequency amplifier stage); four-way power combiner; power supply soft start; 3.5kw DC / DC switching power supply; control and display module; cooling system.



3, TV transmitter power amplifier design



3.1 RF Control Module

RF amplifier input signal is then sent to the module, after processing, then amplified, and then sent to the 100W power amplifier module (RF drive level). Specific process, according to chronological order as follows:

(1) gain control circuit. Adjust amplifier gain adjustment on the front panel potentiometer, the control module through the power amplifier to produce gain control command. The command sent to the module. Adjust the gain of the RF signal. Adjustment range: +1-3 dB.

(2) phase adjustment circuit. Conditioning amplifier phase adjustment on the front panel potentiometer, the control module through the power amplifier to generate phase adjustment command. The command sent to the module, through the MB coupled device to adjust the RF signal phase. Adjustment range: +35-35 degrees.

(3) amplifier. The 3dB coupler RF signal after divided into 2-way, from MRF6522-10 Zoom, and then by 3dB coupler synthesis. These include: input RF signal power measurement, radio frequency drive signal power measurement and pre-bias control.



3.2 270W (final stage) amplifier module

As the digital signal is a wideband signal transmitter, power amplifier module has therefore asked a very good linearity and gain evenly. Class AB power amplifier module consists of two BLF861 LDMOS, bias circuits and matching networks, etc., and use the 3dB directional coupler points as second-class power divider and power combiner. 270W function module circuit diagram shown in Figure 1:



3.3 Control Module

The role of control modules: acquisition sampling signal from the RF module, for processing, production control amplifier source of the command module; the amplifier’s status through the display board, showing the front panel of the power amplifier; to accept commands from the controller, while the work of the state to the control amplifier to go.

Four-way splitter and four 3.4 Synthesizer

Four-way splitter and four synthesizers are realized using microstrip power distribution or power combining. 100W Power Amplifier Module for Quad splitter to the RF amplified output signal, assigned to four 270W input power amplifier module, power amplifier module as the excitation signal. Taking into consideration that each side of the isolation between China and Japan as well as the absorption of reflected power, installation of the balance resistor. In order to reduce the reflected power, designed multi-stage 1 / 4 of the impedance converting circuit.

Four synthesizer to 4 270W Power Amplifier Module RF output signal after amplification, were synthesized. In order to reduce the reflected power, also designed the impedance converting circuit. Four synthesizer input connector through L29, sent to the power combiner.



3.5 Power Supply System

Switching power supply system, will come from the power supply +140 VDC, through the switch transformation method, into a power amplifier module required +32 VDC. Meanwhile, the current and voltage input and output sample signals to the control panel, under the control board’s order, to provide overcurrent protection and overvoltage protection. Switching power supply system block diagram shown in Figure 2:



4 Conclusion



With the further promotion of digital television and popular demand for terrestrial digital television transmitters will be increasing. The current most of the domestic digital TV transmitter also uses imported parts, the transmitter power amplifier is the core component, the localization of the power amplifier will greatly reduce costs. This is the main power in the terrestrial digital television transmitters R & D projects, the completion of the TV transmitter power amplifiers analysis and design, and smooth to the amplifier relevant indicators, and compared to similar foreign par. However, there is still insufficient and need to improve the stability and reliability areas. Moreover, the above R & D only remain in the experiment stage. Can large-scale production, quality assurance, and still meet the corresponding indicators, but also a process that needs to grope in the production and summary.



R & D for the TV transmitter, the development of digital television transmitters focus transmitter power amplifier. TV transmitter in the clear demands of the power amplifier based on the analysis of the power amplifier and the main component of technical indicators and further study of the television transmitter power amplifier design, for our television transmission system for the development of certain research value.

Keywords: TV transmitter; PA; composition and design



1 Introduction



China’s major television stations in the analog transmitter is still the basic stage, the digital transmitter to the development work has just started. In the digital transmitter in general, digital television signals modulated by COFDM mode output frequency analog signals, amplified by the conversion into the part. The modulation, including IF-FT (8K) and IFFT (2K) modes, respectively 6817 and 1705 carriers, each carrier frequency spacing between the very close, so very easy to fall-modulation signal band, causing intermodulation distortion, linear amplifier will seriously affect poor digital transmitter of the key indicators MER (Modulation Error Rate) and the Shoulder (with shoulder). Therefore, the requirement to enlarge part of the linear state should be working on, to affect the signal quality. This content is produced according to the problem, study the basic television transmitter power amplifier module and the design of the corresponding program.



2 TV transmitter power amplifier overview



2.1 The basic requirements for TV transmitter power amplifier

Television broadcasting on the most basic requirement is that the transmitter power amplifier power gain should be high enough. Power amplifier is a broadband amplifier, can cover the entire UHF band, the launch of the channel changes without the need for by-channel adjustment, power amplifier modules at all levels of the most advanced solid-state amplification of imports. Basic requirements are: amplifiers with high linearity, wide dynamic range that the digital modulation signal peak in the dynamic range of the transmitter when there is still a good linearity; even if the defect in a state of the module, the transmitter can still broadcast; transmitter frequency should be high enough precision and frequency stability, low phase noise, to ensure that signals are transmitted at the lowest possible bit error rate and SNR.



2.2 TV Transmitter Power Amplifier Specifications

DVB_T terrestrial digital television transmitters in the conventional power amplifier of the specific indicator is as follows:

Frequency range: 470MHz to 860MHz; amplification by: AB linear amplification; input impedance: 50Ω; Output impedance: 50Ω; return loss: ≥ 15dB; input power: 1W (nominal); output power: 1000W (maximum); power input : 120VDC ± 15%; Power consumption: 1800W (maximum); RF input connector: N Head (Yam head); RF output interface: DIN7/16 head; Protection: RF reflected power is too large (≥ 50W), over current, overheating ; Cooling: Forced air cooling; ambient temperature: -5 ℃ to 45 ℃; Altitude: Up to 3000m; Weight: about 15kg.



2.3 Composition of TV transmitter power amplifier

DVB_T terrestrial digital TV transmitter in the main 500 (W) and 1000 (W), of which 500 (W) with two power amplifier modules, 1000 (w) has four power amplifier modules. Power amplifier generally includes the following nine modules: RF control module; 100W power amplifier module (RF drive level); four-way power divider; 270W power amplifier module (radio frequency amplifier stage); four-way power combiner; power supply soft start; 3.5kw DC / DC switching power supply; control and display module; cooling system.



3, TV transmitter power amplifier design



3.1 RF Control Module

RF amplifier input signal is then sent to the module, after processing, then amplified, and then sent to the 100W power amplifier module (RF drive level). Specific process, according to chronological order as follows:

(1) gain control circuit. Adjust amplifier gain adjustment on the front panel potentiometer, the control module through the power amplifier to produce gain control command. The command sent to the module. Adjust the gain of the RF signal. Adjustment range: +1-3 dB.

(2) phase adjustment circuit. Conditioning amplifier phase adjustment on the front panel potentiometer, the control module through the power amplifier to generate phase adjustment command. The command sent to the module, through the MB coupled device to adjust the RF signal phase. Adjustment range: +35-35 degrees.

(3) amplifier. The 3dB coupler RF signal after divided into 2-way, from MRF6522-10 Zoom, and then by 3dB coupler synthesis. These include: input RF signal power measurement, radio frequency drive signal power measurement and pre-bias control.



3.2 270W (final stage) amplifier module

As the digital signal is a wideband signal transmitter, power amplifier module has therefore asked a very good linearity and gain evenly. Class AB power amplifier module consists of two BLF861 LDMOS, bias circuits and matching networks, etc., and use the 3dB directional coupler points as second-class power divider and power combiner. 270W function module circuit diagram shown in Figure 1:



3.3 Control Module

The role of control modules: acquisition sampling signal from the RF module, for processing, production control amplifier source of the command module; the amplifier’s status through the display board, showing the front panel of the power amplifier; to accept commands from the controller, while the work of the state to the control amplifier to go.

Four-way splitter and four 3.4 Synthesizer

Four-way splitter and four synthesizers are realized using microstrip power distribution or power combining. 100W Power Amplifier Module for Quad splitter to the RF amplified output signal, assigned to four 270W input power amplifier module, power amplifier module as the excitation signal. Taking into consideration that each side of the isolation between China and Japan as well as the absorption of reflected power, installation of the balance resistor. In order to reduce the reflected power, designed multi-stage 1 / 4 of the impedance converting circuit.

Four synthesizer to 4 270W Power Amplifier Module RF output signal after amplification, were synthesized. In order to reduce the reflected power, also designed the impedance converting circuit. Four synthesizer input connector through L29, sent to the power combiner.



3.5 Power Supply System

Switching power supply system, will come from the power supply +140 VDC, through the switch transformation method, into a power amplifier module required +32 VDC. Meanwhile, the current and voltage input and output sample signals to the control panel, under the control board’s order, to provide overcurrent protection and overvoltage protection. Switching power supply system block diagram shown in Figure 2:



4 Conclusion



With the further promotion of digital television and popular demand for terrestrial digital television transmitters will be increasing. The current most of the domestic digital TV transmitter also uses imported parts, the transmitter power amplifier is the core component, the localization of the power amplifier will greatly reduce costs. This is the main power in the terrestrial digital television transmitters R & D projects, the completion of the TV transmitter power amplifiers analysis and design, and smooth to the amplifier relevant indicators, and compared to similar foreign par. However, there is still insufficient and need to improve the stability and reliability areas. Moreover, the above R & D only remain in the experiment stage. Can large-scale production, quality assurance, and still meet the corresponding indicators, but also a process that needs to grope in the production and summary.

Read More

No comments